DE102011009868A1 - Cellular core layer of lightweight panel, has upright and pendant cones or pyramids that are continuously connected to each other, whose side surfaces have identical inclination to form inverted cones or pyramids - Google Patents

Abstract

The cellular core layer has upright and pendant cones or pyramids (1-9) that are continuously connected to each other, where side surfaces of the pendant cones or pyramids are formed with an identical inclination so that inverted cones or pyramids (12-15) are formed between pendant cones or pyramids. The cones or pyramids are comprised of metallic sheets and connected to each other by friction welding process. The structural elements of the cones or pyramids are formed of plastic fiber cement and are interconnected by cementitiuos binder.

Description

The invention relates to a cellular structure for cores of lightweight panels.

Lightweight batten are usually designed as sandwich structures and therefore consist of a lightweight core and tensile and compression-resistant cover layers.

High stiffness and load-bearing capacity are determined by the geometric conditions: As long as the core layer can hold the two cover layers at a fixed distance, the side facing away from the load must be stretched and the side facing the load must be compressed in the case of a possible deflection.

If one has compression and tension-resistant cover layers, which is possible with comparatively little material expenditure, the plate thus remains rigid as long as the core layer does not deform.

The core structures for this are honeycomb or tubular structures that are edgewise, in addition to hard foams, which may not be ductile and therefore are usually heavier.

A disadvantage of honeycomb and tube structures, however, is the small area available for connection to the cover layers and their low shear strength without firm bonding. This has already been postulated by the development of nuclei with double pyramidal structure DE 10 2008 007 5167 respectively. PCT / DE2009 / 000143 overcome.

However, there is a problem that the core layers of such structures are permeable in the transverse direction. This makes them suitable for applications that remain gas-tight even in the case of one-sided damaged cover layers or should not absorb any water, such as: As boat hulls or containers, unsuitable.

Also, the load-bearing capacity of all such structures at kinking load is then at the limit, if the dissipative elements deform themselves. Although this can be avoided by higher wall thickness - by thicker sheets or sheets, or lower thermoforming ratio in the molding - but means higher material usage and greater weight.

In order to overcome these disadvantages, a core structure is proposed, in which two sheets, sheets or foils with pyramid or truncated cones formed therein are joined together in such a way that the edge zones which come into contact between adjacent "hanging" and "standing" formations have positive and / or material locking connected to each other.

So z. B. the edges of the "hanging" and the standing around them "standing" pyramids, or the common tangents "hanging" and the surrounding standing "straight" straight cone welded together, as in particular thermoplastic molding and simultaneous welding of two films in the so-called Twinsheet method is possible.

In addition, it is of course possible, although more difficult, to produce this edge combination by friction welding or, alternatively, by gluing individually formed surface elements, such as those made of sheet metal or fiber cement.

Although core structures are known in which corresponding formations snap into each other, or are connected by welds on the pyramid sections with non-formed parts of the counter sheets or films. Without additional effort, however, these have no closed, dense cells and also require higher wall thicknesses for comparable rigidity - they are therefore considerably heavier.

For in the structure according to the invention significantly higher stiffness and in particular Kickbelastbarkeit is achieved in that - in addition to the locking or connection of the pyramid or truncated cones with the respective opposite surface - the edges of the molded upper and lower structural elements are connected to each other throughout.

This can also improve the problem of screw and nail retention in such structures, because a vertically penetrating fastener of sufficient length in addition to the top layer two material layers of the core - and almost always obliquely - penetrates.

Furthermore, even with random cuts through the structure, it is not possible to encounter deep voids that make it difficult to secure edges to the structure by allowing an application of adhesive to sag into the depth of the structure.

The invention is illustrated in the attached drawings 1 and 2 shown in more detail:

1 shows the formation of upstanding truncated pyramids 1 to 9 (screened) from the base film 10 while exemplarily four from the top sheet 11 downwardly shaped truncated pyramids 12 to 15 so in the lower pyramid blunt 1 to 9 (ruled) are aligned in the Twinsheet method in addition to welding pyramid sections z. B. 16 and 17 , also welding common edges, z. B. 18 to 20 result.

2 shows how when cutting in any direction (the cutting line 21 is chosen as unfavorable) always cut edges of cut surfaces, z. B. 22 to 25 , which provide a pressure-resistant connection with applied along the cut surface end edges (not shown).

3 shows a design with straight truncated cones, z. B. 26 and 27 , It has the advantage of possible higher manufacturing tolerances, because here, as is the case with pyramids which are rectangular or star-shaped in cross section, their edges do not have to be exactly aligned with one another, but when they are joined together forcibly touch tangents (eg. 28 . 29 ) and thus less disturbing a slight offset of the elements. Not possible here is the - also possible - combination of cone and pyramid sections on one or between two foils.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 1020080075167 [0006]
• DE 2009/000143 [0006]

Claims (11)

Cellular core layer for lightweight panels, which is constructed from two sheets, sheets or sheets with molded, congruent conical or pyramidal geometries, characterized in that an identical inclination of the side surfaces of these conical or pyramid shapes allows common touch edges and this between the upright and hanging cone - or pyramids are interconnected throughout. Cellular core structure for lightweight building boards according to claim 1, characterized in that the shaped elements have conical or pyramidal sections, the sectional areas of which are connected to the opposite structural element, but there to the non-formed areas between the formations. Cellular core structure for lightweight building boards according to claim 1 and 2, characterized in that the structure is made of deep-drawn or cold-rolled metal sheets. Cellular core structure for lightweight panels according to claim 3, characterized in that the two sheets are joined together by friction welding. Cellular core structure for lightweight panels according to claim 3, characterized in that the two sheets are bonded together by gluing. Cellular core structure for lightweight building boards according to claim 1 and 2, characterized in that the conical or pyramidal elements are formed from two sheets of fiber plastic or fiber cement. Cellular core structure for lightweight building panels according to claim 6, characterized in that the structural elements are bonded together by cementitious binders, adhesive or laminating resins. Cellular core structure for lightweight panels according to claim 1 and 2, characterized in that the structure is made of two thermoformed thermoplastic films. Cellular core structure for lightweight building boards according to claim 8, characterized in that the formed films are joined together by friction welding. Cellular core structure for lightweight building boards according to claim 8, characterized in that the molded films are bonded together by gluing. Cellular core structure for lightweight panels according to claim 8, characterized in that thermoplastic films are formed in the twin-sheet process and welded together in the same operation.

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