EP1181421A1 - Lightweight construction element in the form of a hollow body contoured honeycomb structure - Google Patents

Abstract

The invention relates to a lightweight construction element in the form of a hollow body contoured honeycomb structure. The construction component (1) is composed of a plurality of individual layers (2, 3, 4), the medium individual layer (3) being composed of a plurality of additional individual layers (23, 24, 25). The individual layers (2, 4, 23, 24, 25) are configured in such a way that they intermesh and firmly interlock with one another thereby producing or defining surfaces that allow that any forces acting upon the elements or individual layers (2, 4, 23, 24, 25) that make up the construction element (1) are absorbed and evened out. Said elements or layers are capable of absorbing not only pressure or lateral forces but also tensile and transverse forces so that they allow for the production of a construction element (1) of less weight but simultaneously high stability. Said construction element (1) can be shaped or deformed as required and can be also extended three-dimensionally so that it can be adapted to the respective conditions in any plane and direction.

Description

 Lightweight construction element in the form of a hollow body honeycomb

Description

The invention relates to a component which is composed of several individual layers, at least one of which has a honeycomb structure.

Components in the form of material plates are known, both the honeycomb structure and the two cover plates being made from paper or cardboard. The honeycomb structure, similar to that of honeycombs, is supported on the cover plates with its approximately perpendicular intermediate walls, so that plates with increased stability and advantageously low weight result. Doors can be made from the corresponding material panels, for example. But they are also used in interior construction and trade fair construction (DE-OS 197 48 192.2). The disadvantage is that the overall construction can be affected by moisture. In addition, the design of the edge area with the corresponding edge reinforcement is problematic because it has to be connected separately to the other parts of the material plate known here. DE-OS 19 22 693.8 discloses a method and a component that is also constructed in a sandwich-like manner. The two metal cover plates and the interposed cell walls or the corresponding honeycomb structure are connected to the cover plates by welding or soldering, the soldering material in particular being guided in such a way that it also attaches to the cell corners and thus connects the cover plate particularly well to the honeycomb structure . Despite the strengthening of the cell corners, it remains essentially that the approximately vertical cell walls are supported on the two cover plates and thus have to transmit the forces to be taken over. Accordingly, the stability of such lightweight honeycomb structures depends almost exclusively on the top layers. The inherent stability of the sandwich core, on the other hand, is negligible. Another disadvantage is the relatively complex production method, as well as the use of different materials and the impossibility, for example also use plastic.

The invention is therefore based on the object of providing a component with minimized weight and having favorable stability and insulation properties.

The object is achieved according to the invention in that the individual layers are designed as a honeycomb partial plate or honeycomb partial film with a very small wall thickness, which have a basic construction and positive and / or negative hollow bodies or partial hollow bodies protruding above them, and when inserted into one another, interlocking and / or mutually claw-shaped and forces acting on them are distributed homogeneously on all honeycomb elements by forming and arranging the embossed individual layers with the respective adjacent individual layers in the flat connection to form a wall, if possible.

In a departure from the state of the art, all elements participate in the force absorption and force distribution to the same extent, so that the peculiarity or the stability of the cover layers is no longer important. Rather, the entire component is uniform throughout, so that it is possible to manufacture and implement both vertical, horizontal and inclined walls and components. Regardless of the particular arrangement of the component, all individual layers or, better said, individual layer parts take part in the force absorption and power transmission and ensure that a component is available that has high stability values and is also extremely sound and temperature insulated . The latter above all in that the individual individual layers either have hollow bodies or partial hollow bodies or form them together, the air contained in the hollow bodies acting as an optimal insulator both against temperature and sound. It is also advantageous that such a component can not only accept vertical loads, but also shear forces or other loads that deviate from the rule, without requiring an increase in the wall thickness or other measures. The corresponding hollow body or partial hollow body can also be used to absorb gas, liquid or inert material and thus, for example, a fire retardant. to provide performance that makes it possible to use it even in extreme situations. The individual component is made of individual nested individual layers, which gives the possibility of specifying a construction which, on the one hand due to the flat design and on the other hand due to the corresponding shape, create wall thicknesses of practically any thickness or with corresponding mutually contacting hollow bodies which bring advantages described above. What is particularly striking is the low weight of such components and the high stability, which is also achieved, among other things, by the flat connection achieved and the formation of stable walls.

A corresponding construction of such a component is achieved in particular in that the hollow bodies or partial hollow bodies assigned to the individual layers are designed with the hollow bodies or partial hollow bodies of other individual layers which represent the middle individual layer and which again have corresponding surfaces. The corresponding partial hollow bodies or hollow bodies become corresponding hollow bodies or even closed hollow bodies if the corresponding individual layers are inserted or nested one inside the other as mentioned above. The separately produced individual layers, the separate structure of which will be discussed further below, are coordinated with one another in such a way that they in each case prejudge the partial hollow bodies or hollow bodies described and also form accordingly when they are assigned to one another. The individual layers or also the partial hollow bodies and hollow bodies have a very small wall thickness, it being pointed out further above that they can be designed, for example, as a partial honeycomb film. These individual thin-walled honeycomb sub-panels are combined and supplemented by the addition when nesting or plugging into one another, so that the abutting of the surfaces of the individual partial hollow bodies or hollow bodies results in the favorable transmission of the forces and on the other hand also an additional stabilization of the entire component structure.

It has proven to be particularly expedient that the hollow bodies or partial hollow bodies assigned to the individual layers with those of other individual layers result in a pyramid or mirror image double pyramid when nesting one inside the other. leads are. This pyramid shape has the advantage that four or more surfaces are available to which the adjacent pyramid or the hollow body or partial hollow body can be placed and adapted, in order to ensure the areal transfer of the forces. The pyramid can be standing, lying or otherwise, or can only be formed when the individual layers are joined together without fear of a reduction in the stability of the entire component.

The pyramids formed by the individual layers of partial hollow bodies or hollow bodies are expediently arranged and designed such that adjacent pyramids or mirror-image double pyramids, which are also formed when nesting one inside the other, lie flat against it, whereby the flat connection of the individual layers creates a static cross wall that absorbs the forces from all sides is trained. It is also pointed out here again that the pyramid shape is particularly well suited to ensure a flat "connection" of the individual pyramid parts to one another. The surfaces of the individual pyramids are all used to create adjacent pyramids of the same or different individual layers, so that it is clear from the description that this creates an optimized construction that provides the low-weight and high-stability properties described above . The result is an advantageous cross wall that can absorb forces from all sides.

For the normal case, it is advantageous if five individual layers are combined to form a combination element, a middle layer being made up of a positive and negative partial hollow body, which is assigned an intermediate single cell layer on both sides and then an individual layer provided with partial hollow bodies. The individual layers are put together or nested, as can be seen from the description, so that an overall stabilized component is obtained which, in particular, ensures a favorable transmission or dissipation of the occurring forces through the pyramid surfaces. In a departure from the previously common sandwich components, the outer individual layers, which in some respects can be referred to as cover plates, are also integrated into the stability structure by: are also equipped on their underside with corresponding hollow bodies or partial hollow bodies which, with those between the individual layer and the middle layer, result in a construction which guarantees the desired stability properties. Because of the hollow bodies or partial hollow bodies assigned to the “cover layers”, shear forces or other unusual forces can also be absorbed without any problems, because these forces are introduced from the “cover layers” into the intermediate layer or intermediate individual layer in such a way that reliable removal or transmission is possible. Since the "cover layers" do not have a stability task or at least no separate or sole stability task, it is possible for the entire combination element to also be curved or otherwise curved, because these edge-side individual layers are made of the same thin-walled material as the interposed individual layers.

A honeycomb structure that can be expanded into the room, or rather, a hollow body structure, can be realized by assigning one or both intermediate individual layers to an adapter single layer or to the subsequent middle layer on both sides to give adapter structures of any height and / or width due to the room construction. The individual adapter layers make it possible to build up a corresponding construction, so to speak, building on the middle layer, so that the component can be cleverly and specifically expanded into the room. Here, too, a homogeneous power transmission is ensured, so that no matter at which point a force acts, this force is evenly distributed over all elements, whereby this combination creates the possibility of building any overall wall thickness.

The expandability of the component into the room is further made possible by the fact that the individual adapter layer alternately has positive partial hollow bodies or hollow bodies and recesses. In this way, for example, a middle layer together with adapater single-cell layers arranged on both sides can be built up to a "single layer" acting on both sides like an edge-side single layer or can be constructed accordingly, whereby the corresponding additional structure is achieved in the room. The strength of the component structure can be varied according to the invention by the choice of the material, the invention providing that the individual layers consist of paper impregnated with liquid plastic, aluminum, steel or plastic films. As already mentioned above, the corresponding individual layers have a wall thickness in the μ range, this being clarified further above in the invention by the term “film”. Depending on the intended use, components can be created precisely for the corresponding intended purpose, which gives both the price and the stability values the possibility of providing optimal components in each case. It is also conceivable that the individual layers consist of woven foils, preferably made of plastic threads or fiber composite materials, in order to be able to further adapt the strength properties and thus the stability values to the respective conditions of use.

According to the invention, the corresponding hollow bodies or partial hollow bodies are to be optimally supported on one another, with the intermediate regions between the pyramids also contributing to this, as will be explained further below. However, according to the invention, these stable individual layers can nevertheless be bent or folded into the respective shape, since according to the invention the edges leading up to the top of the pyramid are perforated and / or slotted. With a corresponding load, this perforation or slitting is not problematic, because the surfaces nevertheless lie against one another and ensure the corresponding transmission or absorption of the forces. Perforating or slitting also allows bending in the area of the individual pyramid without the pyramid or the corresponding hollow body having to be deformed.

A further expedient embodiment provides that the hollow bodies which result in the honeycomb structure are arranged with inclined surfaces, preferably at an angle at an edge. This inclined arrangement of the surfaces is optimal because the entire hollow body can then be included in the line of force without there being sub-areas of the hollow body that are loaded or relieved differently. The oblique surfaces of the hollow bodies lie against one another and pass on the impact force or ensure optimal distribution and thus utilization of the entire honeycomb structure and ultimately also of the corresponding component.

The edge-side individual layers no longer act or serve as a cover layer in the component according to the invention. Rather, they are integrated into the entire component through their hollow bodies or partial hollow bodies. Nevertheless, an outer smooth design is possible in that the edge-side individual layers have hollow bodies or partial hollow bodies on the inside and a flat cover on the outside. The flat cover enables the corresponding components to be stacked, in which case, however, there is no meshing of the components. Components designed in this way are particularly advantageous, for example, when producing partition walls or the like.

The edge-side individual layers also consist of the same material with the same wall thickness as the other individual layers, so that the edge-side individual layers fully participate in the movements or better in the shapes of the other individual layers. This can be supported by the fact that the upper and lower individual layers are made of flexible material or material to be made flexible. For example, it is conceivable here that a softer plastic is used for the individual layers on the edge than for the other individual layers.

If the respective component is brought into the intended shape, it may be expedient to connect the individual individual layers to one another, this being achieved in particular by the hollow bodies or the partial hollow bodies resulting in the honeycomb structure being permanently connected to one another or also detachably taking into account the material properties, preferably welded, glued, screwed or connected by friction. As can be seen from this formulation, the respective shape can also be produced by this connection and then be produced in the same way.

The appropriate pyramid shape for the individual hollow bodies or partial hollow body has already been received. In addition, the invention provides that the partial hollow bodies or hollow bodies of the individual layer are pyramid-shaped and the hollow bodies forming the honeycomb structure are double-pyramid-shaped or a mirror image double pyramid. These double pyramids, or better said mirror image double pyramids, are supported against each other over the lower edges and thus form a stable spatial structure that optimally fulfills the described and required tasks. Here is also a gluing, screwing, etc. possible to effectively connect and couple the pyramids or double pyramids with each other.

The high stability of such components is ensured by the planar support of the elements involved in the honeycomb structure, wherein the edges or the components of the base structure that meet one another can also be included, by spacing the pyramidal partial hollow bodies or the hollow bodies on the base structure to form a spacer , while the segments of the double pyramid-shaped hollow body are connected to one another via an edge strip running parallel to the central axis. This also ensures a flat support in these areas instead of the previously usual linear support.

The stability of the entire component is thus specifically increased. The joining of the individual segments of the double pyramid-shaped hollow body or the honeycomb sub-panels and the secure flat support is favored in that the tips of the segments of the double pyramid-shaped hollow body or the partial hollow body are flattened. This favors threading the honeycomb panels into one another and facilitating the fitting together.

Accurate support of the pyramid tips in addition to the superimposed surfaces of the pyramids or mirror image double pyramids which cooperate with one another is achieved according to the invention in that the flattening at the top of the pyramid or the mirror image double pyramid corresponds to the spacer strip and / or edge strip and ensures a flat support educated is. The tip is also integrated into the planar support structure, as is specifically done - as described - in such a way that the pyramids or mirror image double pyramids can be fitted exactly into or onto the spacer strips or edge strips.

An advantageous balancing of forces or a flexible component arises if the hollow bodies or the surfaces of the individual layers are jointly connected to form a wall by means of an elastic mass. Depending on the thickness and type of elastic mass, the individual layers or the hollow bodies can "move" without loss of stability. This design has advantages in particular in the case of hollow-body contour honeycombs formed from only a few individual layers. Blows can also be absorbed, even the impact of a stone is cushioned.

For insulation, fire retardancy and other reasons, it may be expedient to fill the hollow bodies in whole or in part after connection with a gaseous or liquid medium, an exchange between the individual hollow bodies being achieved via recesses left in the walls. The type of "filling" depends on the application.

A further development is also advantageous in which the so-called neutral fibers are connected with the flat connections to the next neutral fiber and the intermediate layers provide the intermediate spaces, the surfaces of which also receive a connection.

The invention is characterized in particular in that all the elements involved in the construction of such a honeycomb structure participate in the absorption of forces acting on the component. This means that the forces are absorbed by the outer plane and passed on to the subsequent elements, ie the individual layers and their individual parts. The individual elements of such a component are thus jointly responsible for the stability of the entire component. The cover layers or individual layers on the edge no longer need to be particularly stable, but have the same wall thickness as that other individual layers and usually consist of the same material. However, they are not only simpler in terms of their structure, they also no longer hinder the shaping of the entire component, since they can be bent together with the intermediate individual layers or otherwise deformed in order to give the component the desired shape. The individual layers are also specified in terms of the "internal structure" in such a way that the overall component can be shaped accordingly. The individual hollow bodies or partial hollow bodies are slit or otherwise weakened at the edges leading to the pyramid tip, so that they do not conflict with the corresponding shape. It is particularly advantageous that with the aid of the corresponding individual layers, components of practically any wall thickness can be produced, but with an outstandingly low overall weight. In addition, it is possible not only to adapt the entire wall thickness of such components to the prevailing conditions, but also to extend them in the plane, because the individual layers can be interlocked, arranged and assembled in such a way that it is practically possible without transitions, correspondingly large components to realize. This creates and enables a spatial construction that is not conceivable with any other component. Finally, it is a further advantage that it is possible with such components to use a wide variety of materials in order to enable adaptation to a wide variety of tasks.

Further details and advantages of the subject matter of the invention emerge from the following description of the associated drawing, in which a preferred exemplary embodiment is shown with the necessary details and individual parts. Show it:

FIG. 1 shows a component with an internal honeycomb structure,

Figure 2 shows a hollow body in the form of a double pyramid in

Side view,

3 shows the double pyramid-shaped hollow body in

Top view, FIG. 4 shows a top view of an individual layer on the edge from the inside,

FIG. 5 shows a perspective view of the interior of the individual layer on the edge according to FIG. 4,

FIG. 6 shows an exploded view of a five-part component,

FIG. 7 shows the component according to FIG. 6 shortly before the individual layers are pushed into one another or clawed,

Figure 8 shows the perspective of Figure 7 and

FIG. 9 shows an exploded drawing of an eleven-part component with an adapter single layer connecting the individual layers.

Figure 1 shows a component 1 in the finished state. The upper edge-side individual layer 2 is partially opened in order to make the honeycomb structure 3 visible, which is supported on the upper edge-side individual layer 2 and on the lower edge-side individual layer 4. The honeycomb structure 3 is shown here in simplified form. As explained further below, the individual layers 2, 3, 4 are integrally formed.

The side edge 5 of the component 1 is shown here as a smooth plane, as is the edge-side individual layer 2, which is achieved there by the fact that a cover 29 is applied to the edge-side individual layer 2, which is shown further below.

The honeycomb structure 3 consists of a multiplicity of individual layers 23, 24, 25 with hollow bodies 7, 8, 9 or partial hollow bodies 26, 27; the corresponding reference numerals can be found in the following figures.

Both the edge-side individual layer 2 as well as the edge-side individual layer 4 and the honeycomb structure 3 interposed therebetween with the corresponding individual layers 23, 24, 25 consist of partial honeycomb panels 17 of low wall thickness. This honeycomb panel 17 is even usually designed as a partial honeycomb film, ie it has a wall thickness in the μ range.

The honeycomb structure 3 or the individual layers 2, 4, 23, 24, 25 are formed with hollow bodies 7, 8, 9 according to FIGS. 2 and 3 or partial hollow bodies 26, 27 according to FIG. 6. For the sake of simplicity, a distinction is not clearly made in the following between hollow bodies 7, 8, 9 and partial hollow bodies 26, 27, because when the individual layers 2, 4, 23, 24, 25 are joined together, hollow bodies 7, 8, 9 as well as partial hollow bodies 26 are again formed , 27 form, which lead to the honeycomb structure 3 or to the component 1.

The individual hollow bodies 7, 8, 9 according to FIG. 2 and FIG. 3 generally form pyramids 14, 14 'or mirror image double pyramids 19, the individual segments 20, 21 serving to achieve total support of the individual elements of the honeycomb structure against one another and ensure. As can be seen in FIGS. 2 and 3 and the other figures, the pyramids 14 or mirror-image double pyramids 19 are particularly suitable for supporting the individual elements in this manner because surfaces 10, 11 are available which are correspondingly offset, and which are also so large that the corresponding forces acting on the component 1 can be safely absorbed and transmitted.

The mirror image double pyramid 19 consists of the two pyramids 14, 14 'which are connected to one another via a coupling web 22. The central axis 30 separates the two elements or they are connected to one another along this central axis.

At the tips 12 of the individual pyramids 14, 14 ', flattenings 13 are provided, so as to enable an additional inexpensive support of the individual parts or individual elements on the edge strips 31 or the spacer strips 18 or the base construction 16.

While the “dividing line” in FIG. 2 joins the two pyramids 14, 14 ′ to form a double pyramid 19, the central axis 30 according to FIG. 3 at the same time the dividing line that leads through the flattened tips 12. It is not discernible that the edges 15, 15 'can be perforated or can be cut open in order to allow the corresponding individual layer and also the entire component 1 to be bent or bent, without the need for excessive forces.

FIG. 4 shows an individual layer 2 or 4 on the edge, which has hollow bodies 7, 8 or pyramids 14 on the inside 28. These individual pyramids 14 are all of the same dimensions and connected to one another via the basic construction 16. This basic construction 16 at the same time forms the spacer strips 18, which ensure that the individual pyramids 14 are arranged at the same distance from one another and which at the same time ensure that the partial hollow bodies formed when the individual individual layers 2, 4, 23, 24, 25 are pushed together 26, 27 or 7, 8, 9 can also be supported with their tips 12 on this spacer strip 18. This optimizes the stability of the corresponding overall construction of the component.

By using the same reference number 18 for all basic constructions 16 running between the pyramids 14, it is made clear that they should all have the same dimensions. They are provided with 18 'and 18 ".

Figure 5 corresponds in principle to the representation according to Figure 4 only that a perspective is shown here, which at the same time makes it clear that the corresponding surfaces 10, 10 ', 11, 11' all support one another and thus the forwarding of the occurring or impacting Forces are involved. The corresponding pyramids 14 also formed here on the inside 28 have the same shape and thus also the same surfaces 10, 11. The basic construction 16 or the spacer strips 18 run between the individual pyramids 14.

FIG. 6 shows a component 1, which here is composed of a total of five individual layers 2, 4, 23, 24, 25. 2 and 4 denote the edge-side individual layers, while the middle layer 25 and the middle individual layer 25 with their partial bodies 26 and 27 projecting on both sides simultaneously as a coupling element for the individual layers 23, 24 and then the edge-side individual layers 2, 4 is used. It can be seen that the so-called middle layer, that is to say the middle individual layer 25, has pyramids 14 and 14 ′ protruding on both sides in order to enable and favor clawing or connection to the correspondingly formed individual layers 23 and 24, and then also complementary hollow body 7, 8, 9 or partial hollow body 26, 27 arise.

The component 1 shown in FIG. 6 is shown in FIG. 7 shortly before the assembly, whereby this is also intended to indicate optically that the individual layers 2, 4 and the individual layers 23, 24, 25 on the edge can be inserted and nested in such a way that they can be nested results in a flat component of high stability and low weight, the insulating effect of such a component resulting as a further advantage.

FIG. 8 finally shows the component according to FIG. 6 and FIG. 7 in a perspective illustration likewise shortly before the assembly, it being clear here that the edge-side individual layers 2, 4 have no cover here.

FIG. 9 finally shows a component 1 which consists of a total of eleven individual layers 2, 4, 23, 24, 24 'and 25, the individual layers 23 and 24 and 24' each being present in duplicate. The individual layers 2, 4 and also the individual layers 23, 24, 25 are known from the previous figures, two additional individual layers 33 being added here, which make the central individual layer 25 an edge-side individual layer 2 and 4 on both sides, because they alternate with Pyramids 14 and recesses 34 are provided and thereby result in a coupling surface on both sides of the central individual layer 25, which produce those on the inside 28 of the edge-side individual layer 2 or 4. An expansion of a corresponding component according to FIGS. 6, 7, 8 into the room is thus possible, so that components 1 of practically any wall thickness can be produced.

However, the individual figures also show that the special design of the individual layers 2, 4, 23, 24, 25 and also 33 give the possibility of speaking offset arrangement of the individual layers 2, 4, 23, 24, 25, 33 to bring about an expansion in the plane, which makes the expansion of the component 1 into a very large-area component possible.

All of the features mentioned, including those that can be seen in the drawings alone, are regarded as essential to the invention, alone and in combination.

Claims

claims

1. Component, which is composed of several individual layers (2, 3, 4), of which at least one individual layer has a honeycomb structure, characterized in that the individual layers (2, 3, 4) as a very thin wall panel part (17) or partial honeycomb film are formed, which have a basic construction (16) and positive and / or negative hollow bodies (7, 8, 9) or partial hollow bodies (26, 27) protruding above them, and when they are inserted into one another, they interlock and / or are clawed together and open the forces acting on all honeycomb elements are designed to be homogeneously distributed by forming and arranging the embossed individual layers (2, 3, 4) with the respective adjacent individual layers in the flat connection to form a wall, if possible.

2. Component according to claim 1, characterized in that the individual layers (2, 4) assigned hollow body (7, 8, 9) or partial hollow body (26, 27) with the hollow body (7, 8, 9) or partial hollow body (26, 27) of other individual layers (23, 24, 25) representing the middle individual layer (3) and again corresponding surfaces (10, 11).

3. Component according to one of the preceding claims, characterized in that the hollow layers (7, 8, 9) or partial hollow bodies (26, 27) assigned to the individual layers (2, 4, 23, 24, 25) with those of other individual layers (2, 4, 23, 24, 25) when nesting one another, a pyramid (14) or mirror image double pyramid (19) is produced.

4. Component according to one of the preceding claims, characterized in that of the individual layers (2, 4, 23, 24, 25) from partial hollow bodies (26, 27) or Hollow bodies (7, 8, 9) formed pyramids (14) are arranged and designed so that adjacent pyramids (14 ', 14 ") or mirror image double pyramids (19), also formed when nesting one inside the other, lie flat against it, with the flat connection of the individual layers (2, 4, 23, 24, 25) a static cross wall is created, which is designed to absorb the forces from all sides.

5. Component according to one of the preceding claims, characterized in that five individual layers (2, 4, 23, 24, 25) are combined to form a combination element, with a single layer having positive and negative partial hollow bodies (26, 27) as the middle layer (25) is used, which is assigned an intermediate single-layer (23, 24) on both sides and then an individual layer (2, 4) provided on one side with partial hollow bodies (26) or (27).

6. Component according to one of the preceding claims, characterized in that one or two intermediate individual layers (23, 24) an adapter single layer (33) or the subsequent middle layer (25) on both sides adapter individual layers (33) structure of any height and / or width are assigned by the spatial construction.

7. Component according to one of the preceding claims, characterized in that the adapter single layer (33) has alternately positive partial hollow bodies (26, 27) or hollow bodies and recesses (34).

8. Component according to one of the preceding claims, characterized in that the individual layers (2, 4, 23, 24, 25, 33) made of paper impregnated with liquid plastic, aluminum. Foil made of steel or plastic.

9. Component according to one of the preceding claims, characterized in that the individual layers (2, 4, 23, 24, 25, 33) consist of woven foils, preferably woven from plastic threads or fiber composite materials.

10. The component according to one of the preceding claims, characterized in that the edges (15) leading up to the top (12) of the pyramid (14) are perforated and / or slotted.

11. Component according to one of the preceding claims, characterized in that the honeycomb structure (3) resulting hollow body (7, 8, 9) with inclined surfaces (10, 11), preferably on an edge (15) are arranged obliquely.

12. Component according to one of the preceding claims, characterized in that the edge-side individual layers (2, 4) have hollow bodies or partial hollow bodies (26, 27) on the inside and a flat cover (29) on the outside.

13. Component according to one of the preceding claims, characterized in that the upper and lower individual layers (2, 4) are made of flexible material or material to be made flexible.

14. The component according to one of the preceding claims, characterized in that the hollow body (7, 8, 9) and or the partial hollow body (26, 27) the honeycomb structure (3) resulting permanently or also releasably connected to one another taking into account the material property, preferably to one another welded, glued, screwed or connected by friction.

15. Component according to one of the preceding claims, characterized in that the partial hollow body (26, 27) or hollow body (7, 8, 9) of the individual layers (2, 4) pyramid-shaped and the hollow body (7) forming the honeycomb structure (3 , 9) are double pyramid-shaped or a mirror image double pyramid (19) is formed.

16. The component according to one of the preceding claims, characterized in that the pyramid-shaped hollow part (26, 27) or the hollow body (7, 8, 9) on the base construction (16) are spaced apart to form a spacer strip (18) while the segments (20, 21) of the double pyramid-shaped hollow bodies (7, 8, 9) are connected to one another via an edge strip (17) running parallel to the central axis (29).

17. The component according to one of the preceding claims, characterized in that the tips (12) of the segments (20, 21) of the double pyramid-shaped hollow body (7, 8, 9) or of the partial hollow body (26, 27) are flattened.

18. Component according to one of the preceding claims, characterized in that the flattening (13) at the top (12) of the pyramid (14) or the mirror image double pyramid (19) with the spacer strip (18) and / or edge strip (31) corresponding and is designed to ensure flat support.

19. Component according to one of the preceding claims, characterized in that the hollow bodies (7, 8, 9) or the surfaces of the individual layers (2, 4, 23, 24, 25, 33) are connected together by means of an elastic mass to form a wall are.

20. Component according to one of the preceding claims, characterized in that the hollow body (7, 8, 9) are completely or partially filled after connection with a gaseous or liquid medium.

21. The component according to any one of the preceding claims, characterized in that the individual layers (2, 4, 23, 24, 25, 33) in the walls and / or the spacer strips (18) have recesses which, after nesting and connecting, to flow through or circulating gas or liquid flow.

22. Component according to one of the preceding claims, characterized in that the so-called neutral fibers are connected to the flat connections to the next neutral fiber and the intermediate layers provide the intermediate spaces, the surfaces of which also receive a connection.