WO1985005396A1

WO1985005396A1 - Façade panel and wall built with façade panels

Info

Publication number: WO1985005396A1
Application number: PCT/DE1985/000168
Authority: WO
Inventors: Manfred Breuhan
Original assignee: Elefant-Chemie Fritz Breuhan
Priority date: 1984-05-16
Filing date: 1985-05-15
Publication date: 1985-12-05
Also published as: DE3561667D1; ATE32618T1; EP0182823B1; DE3418145A1; EP0182823A1

Abstract

The faade panels (10, 26) are provided with folds (12, 30) on their sides. Said folds form grooves in the bearing area of the faade elements (10, 26) arranged edge to edge, and wherein is introduced an armour layer (24) which will be coated with mortar. The faade plates (10, 26) are provided on their upper surface with facing elements (22). Facing elements (22) will also be secured on the connection zones so as to give the aspect of a continuous weather-proof wall.

Description

Facade panel as well as manufactured with facade panels

Wall element

The invention relates to a facade panel consisting of a lower insulating layer, a reinforcement and an upper plaster layer. In addition, the invention is concerned with a wall element made with facade panels.

As is known, facade panels of the type mentioned above can be used in a variety of ways, since they not only allow a facade to be redesigned subsequently, but also have the effect of thermal insulation. An important and preferred area of application is therefore in the field of modernization of old buildings.

But facade panels are also often used in new buildings, for example to give the house a pleasing appearance. Furthermore, the facade panels are also used in light-weight houses (e.g. made of wood) to subsequently give the impression of a solid house. Finally, the facade panels are also particularly suitable for cladding interior walls, for example in basements.

Overall, you can use the facade panels because of their attribute considerable importance to the many possible applications. Contrary to this meaning, however, there are still disadvantageous circumstances of the known facade panels, whereby these disadvantages are primarily due to the connection of several facade panels to a large facade surface.

The known facade panels have, among other things, relatively handy and small dimensions for transport reasons, and therefore if a large area is to be covered, several individual facade panels must be arranged side by side or one above the other. The connection of the individual facade panels to one another is of particular importance.

So that the month can be carried out by a non-specialist, if possible, the aim is to make the connection quite simple, and it is known to make the connections between the individual facade panels according to the tongue and groove principle. In other known facade panels, the sides to be connected to one another are serrated or stepped, in which case the corresponding projections on one panel engage the corresponding recesses in the other panel on two adjacent facade panels. Although a secure connection between the individual facade panels can be achieved in this way when covering a large area with a large number of facade panels, it has been shown in practice that the connection points become optically visible after a long time. whereby the impression of a full-surface wall is destroyed. Rather, the connection points of the wall that have become visible give an optically unattractive appearance, which allows the individual facade panels to protrude.

The visibility of the connection points is due to weather-related influences; Rain and dirty water, in particular, have the effect that the connection points appear visually after a long time. It is therefore not possible with the known facade panels to clad a facade element consisting of several panels or a large-area wall, the impression of a full-surface wall being retained.

This is where the invention intervenes, which, in order to avoid the disadvantages described, is based on the task of creating a facade panel which enables simple connection to adjacent facade panels, this connection also under the action of rain. and dirty water (also from sun and frost) remains and is not visually visible.

This object is achieved in the facade panel mentioned in the preamble of claim 1 in that the facade panel has a fold in the area of the plaster layer on at least two sides, and that flat facing bricks are arranged on the plaster layer.

In the case of the invention, adjacent facade panels can be arranged bluntly next to one another, the then adjacent folds forming a connecting area. A reinforcement layer can be embedded in this connection area and then plastered. As a result, the connection area formed by the folds between two adjacent facade panels is completely filled and covered. In the area where the two facade panels are butted below the folds, no rain or dirty water can get in from the outside, so that this connection area is not visible after a long time even under the influence of water. The invention enables for the first time the production of a really full-surface wall, which consists of several individual facade panels. In the invention, the individual facade panels are already provided with flat facing bricks, and after a plurality of facade facing panels have been arranged next to one another or also one above the other, and after the reinforcement layer has been provided, such flat facing bricks can also be glued to this reinforcement layer in the connection area, as a result of which full surface overall impression of the finished facade element is still supported. In retrospect, it is no longer visually recognizable that the facade element was composed of several individual facade panels.

In order to achieve a particularly secure hold, the reinforcement layer can also be glued into the connection area formed by the two folds. If the reinforcement layer has reinforcement with a metal grid, there is also the possibility of providing claws which are introduced into prefabricated bores which are located in the rebate areas. In all cases, a mechanical fastening of the reinforcement layer and a connection of adjacent facade panels is achieved, and on the other hand it is ensured that the connection point remains invisible after completion and thus the desired impression of a full-surface wall is created and also under the influence of the weather is maintained.

Other advantageous refinements and developments of the invention are described in the subclaims and. can be seen in the drawing.

The invention is explained in more detail below on the basis of the exemplary embodiment shown in the drawing. Show it:

1 is a cross-sectional view of a facade panel,

Fig. 2 is a schematic perspective view of a facade panel, and

3 shows the connection of two adjacent facade panels to a facade element.

The facade panel 10 shown in FIGS. 1 and 2 consists of a lower insulating layer 16, a reinforcement 18 located above it and an upper plaster layer 20. Flat facing bricks 22 are laminated or glued onto the plaster layer 20. The flat Blenders 22 give the facade panel the impression of a brick wall.

In the area of the plaster layer 20, the facade panel 10 has a recess in the form of a fold 12 and 14 on each of two opposite longitudinal sides. The flat facing bricks 22 on the plaster layer 20 extend at most to the edge formed by the folds 12 and 14, but leave the folds 12 and 14 themselves free.

3, it will be explained below how several — in the example shown, two facade panels 10 and 26 — can be put together to form a full-surface facade element. For reasons of clarity of the drawing, only the facade panels 10 and 26 are shown, the lower wall to which the facade panels are applied is therefore not shown.

The two facade panels 10 and 26 abut each other with their adjacent folds 12 and 30. As a result, a depression or a connecting area is formed in the area of the two folds 30 and 12, in which a reinforcing layer 24 is embedded. The Reinforcement layer 24 overlaps both the fold 12 of the right facade panel 10 and the fold 30 of the left facade panel 26.

The reinforcement layer 24 consists of a reinforcement fabric known per se, for example a glass fabric coated with composite mortar. A metal grid can also be used, which is provided with claws (not shown). These claws can then be introduced into prefabricated bores in the area of the folds 12 and 30.

After the reinforcement layer 24 has been embedded in the connecting area formed by the two folds 12 and 30, it is then plastered, so that a seamless transition point is created between the two plaster layers of the adjacent facade panels 12 and 30. Next, flat facing bricks 22 are glued on in this connection area, some of which are shown in broken lines in FIG. 3. After the entire connection area has been provided with such flat brackets 22, there is the visual impression of a full-area facade element 28 in which the connection point or the connection area is no longer visually visible. The flat facing bricks 22 can consist of quartz sand with synthetic resin components and can be both glued and laminated onto the plaster layer 20. If the flat facing bricks 22 according to FIG. 1 are arranged in an offset from one another on the facade panel 10, this offset will be retained later when the flat facing bricks 22 are stuck on in the area of the reinforcement layer 24, so. that the visual impression of a full-surface wall is guaranteed.

The connection of two adjacent facade panels 10 and 26 explained with reference to FIG. 3 can also be used in a corner configuration if two facade panels abut one another at an angle.

The facade panels according to the invention have a relatively light weight, so that they are easy to transport without large transport costs. A facade element 28 consisting of a plurality of facade panels can also be easily produced in the form of self-assembly without the need for skilled workers.

In connection with the reinforcement layer 24 provided in the invention, it should also be noted that this advantageously compensates for expansion between adjacent facade panels 10, 30 allows.

For the rest, the reinforcement layer 24 prevents - as already mentioned above - rain or dirty water from the outside from reaching the connection area where adjacent facade panels 10, 30 are butted against each other. In the known facade panels, this connection area is a critical point because, due to a capillary effect, water dripping down is absorbed here, as a result of which the connection point is then visible. In contrast, in the invention, no rainwater can penetrate capillary, so that the impression of a full-surface wall is obtained and remains.

Claims

Patent claims

1. facade panel, consisting of a lower insulating layer, a reinforcement and an upper Putz¬ layer, characterized in that the facade panel (10) in the region of the plaster layer (20) has a fold (12, 14) on at least two sides, and that flat facing bricks (22) are arranged on the plaster layer (20).

2. Facade panel according to claim 1, marked thereby ^{'characterized} that the insulating layer (16) consists of a foamed plastic ge (polystyrene).

3. facade panel according to claim 1 or 2, characterized in that the reinforcement (18) is formed by Glassei¬ dengewebe.

4. facade panel according to claim 1 or 2, characterized in that the reinforcement (18) is formed by plastic fabric.

5. facade panel according to claim 1 or 2, characterized in that the reinforcement (18) is formed by Streckme¬ tall.

6. Facade panel according to one of the preceding claims 1-5, characterized in that the flat facing bricks (22) are designed in the manner of rectangular stones and are spaced apart on the plaster layer (20).

7. Facade panel according to one of the preceding claims 1-5, characterized in that the flat facing bricks (22) are glued to the plaster layer (20).

8. With facade panels according to one of the preceding claims, the facade element produced, characterized in that at least two facade panels (10, 26) with adjacent folds (12; 30) butt against one another. that a reinforcing layer (24) is embedded in the connecting area formed by the adjacent folds (12; 30) and that flat facing bricks (22) are glued onto the reinforcing layer (24).

9. facade element according to claim 8, characterized ge indicates that the reinforcing layer (24) consists of a coated with composite mortar glass fabric in the form of egg nes grid.

10. facade element according to claim 8, characterized ge indicates that the reinforcing layer (24) is formed by textile fibers.

11. Facade element according to claim 1, characterized ge indicates that the insulating layer (16) consists of polyurethane (PU).