DE20013321U1 - Formwork panel - Google Patents

Description

LEMCKE · BRDMMER & PARTNER

PATENT ATTORNEYS

BISMARCKSTR. 16 · D-"761 33 KARLSRUHE

31 July 2000 18 215 (B/hl)

Kurt Fanelsa

Konrad-Adenauer-Strasse 97
76571 Gaggenau

Switchboard l

LEMCKE-BROMMERSPARTNER

PATENT ATTORNEYS

BISMARCKSTR. 16 · D-761 33 KARLSRUHE

31 July 2000 18 215 (B/hl)

Description

The invention relates to a formwork panel for the production of concrete components, wherein the formwork panel consists largely of plastic and optionally has reinforcing elements.

Such formwork panels are made of wood, plastic, metal, and also in multi-layer composite construction. They can also be combined with metal frames, especially when large-area components need to be formed in a short space of time.

Compared to wood, plastic formwork panels have the advantage of a longer service life because they are more resistant to the attack of fresh concrete.

The present invention is based on the object of improving formwork panels made of plastic in such a way that they are lighter than before while maintaining the same strength properties, in particular with respect to the formwork pressure, so that their handling on the construction site and during transport is made significantly easier. The formwork panel according to the invention should also be characterized by high wear resistance and durability.

This object is achieved according to the invention in that the formwork panel consists at least predominantly of chemically foamed and hardened duroplast made of at least two components that react with one another and in that it has a wear-resistant coating at least on its side facing the concrete.

The formwork panel is no longer made of compact thermoplastics or thermoplastics that are slightly expanded by physical means, but rather of a curable reaction foam system with adjustable space

weight. Their weight is thus reduced to a fraction of that of conventional plastic formwork panels.

In order for the rigid foam used according to the invention to have a sufficiently stable surface on the side facing the concrete, a wear-resistant coating is applied there. This coating also increases the flexural rigidity of the formwork panel and is therefore also expediently applied to its rear side.

In a further development of the invention, it is recommended to reinforce the stiffening of the formwork panel by integrating reinforcing elements into the foamed duroplast, in particular by foaming them in. These reinforcing elements preferably consist of strips that are arranged upright in relation to the formwork panel plane so that they provide high bending resistance and pressure stability. They can also be angled once or several times for this purpose.

To ensure that these reinforcing elements do not impair the homogeneous distribution of the foaming plastic, they are provided with numerous recesses for the foam to pass through. They can be arranged lengthways and/or crossways, although a grid-like arrangement of the reinforcing elements is recommended in order to ensure constant strength regardless of the installation situation.

Alternatively or additionally, the reinforcing elements can also consist of a frame that completely or partially surrounds the formwork panel and which can also be profiled, and/or of intermediate layers that are foamed in or arranged between the rigid foam and the coating.

Materials that can be used for the reinforcement elements include metal, plastic, glass fiber, carbon fiber laminates and others.

The foamed thermoset preferably consists of polyurethane, with polyol, polyisocyanate and water being used as reactants. However, it is also within the scope of the invention to make the thermoset from epoxy resin instead.

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to produce, in particular based on bisphenol A and epichlorohydrin and to use polyamines and polycarboxylic acid anhydrides and a suitable blowing agent for curing.

For the wear-resistant outer coating, a slightly foamed or preferably an unfoamed plastic is used, in particular unfoamed polyurethane.

The foamed thermoset as well as the outer coating can each consist of several layers of possibly different materials.

The invention described can also be used excellently for formwork panels with external frames. In this regard, reference is made to DE 200 12 166.9 by the same applicant, the content of which is also made the subject of the present application.

In a formwork panel combined with a frame in this way, the frame has a circumferential recess in which the formwork panel lies with its edge. The present invention is then implemented in such a way that the wear-resistant coating, at least its outer layer, also simultaneously fills the more or less large gaps that usually run between the formwork panel and the frame. For the application of the coating, reference is made to the disclosure content of DE 200 12 166.9.

Further features and advantages of the subject matter of the application emerge from the following description of embodiments based on the drawing;

Figure 1 shows a section of a formwork panel with an outer frame in an oblique view;

Figure 2 shows the same oblique view of a reinforced formwork panel that does not require an external frame;

Figure 3 shows a similar formwork panel in an alternative design and Figure 4 shows a similar formwork panel with an inner frame.

In Figure 1, one can see two parallel longitudinal struts 1a and an intermediate strut 1b of a frame 1, which can be imagined as a rectangular, circumferential frame. Its longitudinal struts and also the cross struts (not shown) have a circumferential recess 1c on their upper inner edge and the actual formwork panel 2 lies in this recess, whereby a circumferential gap 3 remains between the outer edge of the formwork panel 2 and the frame 1, which is more or less large.

It is now essential that the formwork panel 2 consists in its core 2a of a chemically foamed, hardened thermoset, which was obtained from at least two components that react with one another, with water and/or air and/or hydrofluoroalkanes being added to achieve the desired degree of foaming or the desired bulk density, and that this core has a wear-resistant coating 2b made of plastic at least on the side facing the concrete - in the exemplary embodiment on all sides. So-called integral foam can also be used for the core 2a, the density of which increases towards the outside. Both the core 2a and the coating 2b can consist of polyurethane or epoxy resin, but with the crucial difference that the core 2a is foamed in order to achieve the lowest possible density, whereas the coating 2b is unfoamed or hardly foamed in order to produce a hard, wear-resistant surface.

The coating 2b also serves to fill the gap 3 between the core 2a of the formwork panel and the frame 1, so that a formwork surface is obtained that is seamlessly connected to the top of the frame 1 and runs at the same height as it or - contrary to the drawing - also covers the frame. Its density is - apart from the gap area - a few millimeters.

The coating is applied by spraying, pouring or brushing. In this respect, reference is made in full to the aforementioned DE 200 12 166.9.

It is also essential that the formwork panel has reinforcement elements. A wide variety of shapes and materials can be considered for this. For example,

Tensile and compressive strength intermediate layers can be arranged in or under the coating to ensure that the formwork panel has a sufficiently high flexural rigidity.

In Figure 1, the reinforcing elements consist of numerous intersecting strips 4 that run parallel to the longitudinal and transverse struts of the frame 1 and are arranged upright to the formwork panel plane. They are foamed into the core 2a in a force-fitting and form-fitting manner. So that they do not impair the expansion of the foam and the individual chambers between the grid-shaped strips are connected to one another, the strips have a large number of recesses in the form of through-openings 5.

Depending on the stiffening effect of the reinforcing elements, the formwork panels can also be used without the frame 1, which is explained in the following figures.

Figure 2 shows a formwork panel with a greater wall thickness, which can preferably be used as a lightweight ceiling formwork. It also consists of a core 2a made of rigid foam and a wear-resistant plastic coating 2b, but contains reinforcement elements made of much more stable strips 4 inside than in Figure 1. The strips are also arranged here along the peripheral side edges of the core 2a, so that they form a kind of inner frame for the core 2a.

In Figure 1 as well as in Figure 2, the reinforcing elements can consist of individual strips, the number of which, depending on the stability requirement, are put together or otherwise connected before the foaming process in order to then form a form-fitting and force-fitting unit with the expanding, hardening reaction foam.

Figure 3, on the other hand, shows a variant without crossing strips. Instead, the desired stiffening is achieved here by a sheath 6 surrounding the core 2a. This sheath can in turn be made of metal, plastic, glass fiber or carbon fiber laminates, but also of cellulose fibers. It bonds with the foam when it hardens, whereby

Recesses 5 in the casing 6 allow local penetration of the foam and thus enable a positive locking.

On the outside, the casing 6 is surrounded by the coating 2b already described.

In Figure 4, the reinforcing elements are also formed by a casing. Here, however, the casing 7 does not completely enclose the core 2a, but only partially on one side, in particular the side facing away from the concrete. It can be seen that it runs out in several bends 7a, with these bends running into the core 2a. They therefore increase the bending stiffness of the formwork panel.

On its outside, the casing 7 as well as the non-coated area of the core 2a is again surrounded by the wear-resistant coating 2b.

The embodiments show that there is great scope for the structural design of the reinforcing elements without thereby departing from the scope of the present invention.

Claims (12)

1. Formwork panel for producing concrete components, wherein the formwork panel ( 2 ) consists largely of plastic and optionally has reinforcing elements, characterized in that the formwork panel ( 2 ) consists at least predominantly of chemically foamed and hardened duroplast ( 2a ) made up of at least two components which react with one another and that it has a wear-resistant coating ( 2b ) at least on its side facing the concrete. 2. Formwork panel according to claim 1, characterized in that its reinforcing elements ( 4 , 6 , 7 ) are foamed into the duroplast ( 2a ). 3. Formwork panel according to claim 1, characterized in that its reinforcing elements consist of strips ( 4 ) which are arranged upright with respect to the formwork panel plane. 4. Formwork panel according to claim 1, characterized in that the reinforcing elements ( 4 ) have recesses ( 5 ) for the passage of the foam. 5. Formwork panel according to claim 1, characterized in that the reinforcing elements ( 4 ) are arranged crosswise. 6. Formwork panel according to claim 1, characterized in that the reinforcing elements ( 4 ) consist of a frame ( 6 , 7 ) and/or intermediate layers. 7. Formwork panel according to claim 1, characterized in that the reinforcing elements ( 4 ) consist of metal, plastic, glass, carbon or cellulose fibers. 8. Formwork panel according to claim 1, characterized in that the foamed duroplast ( 2a ) consists of polyurethane. 9. Formwork panel according to claim 1, characterized in that the foamed duroplast ( 2a ) consists of epoxy resin. 10. Formwork panel according to claim 1, characterized in that the coating ( 2 b) consists of slightly foamed or unfoamed plastic. 11. Formwork panel according to claim 1, characterized in that the coating ( 2 b) consists of unfoamed polyurethane. 12. Formwork panel which is combined with an outer frame ( 1 ), the frame ( 1 ) having a circumferential recess ( 1c ) in which the formwork panel ( 2 ) lies with its edge, in particular according to claim 1, characterized in that the coating ( 2b ) simultaneously also fills the gap ( 3 ) running between the formwork panel ( 2 ) and the frame ( 1 ) on the side facing the concrete.