DE19606195A1 - Folded honeycomb structure esp. used as sandwich core layer - Google Patents

Abstract

The honeycomb structure consists of similar cells in rows. The cells have side walls attached to each other to form a ring and delineated on the open sides of the cells by outer layers. In at least one covering layer the cells are partly or completely bridged by bridging sections (13,16). The flat body from which the honeycomb structure is folded is divided into a first quantity of continuous strip parts and into a second quantity of strip parts. The second strip parts have incisions and bridging sections joining the first strip sections. The first strip parts are folded by 90 deg. in relation to the second strip parts.

Description

The invention relates to a folded honeycomb a plurality of cells and a method for Production of the folded honeycomb.

Sandwich core layers are usually made from honeycombs manufactured, the cells of which are equilateral hexagons form. Then come to this honeycomb layer Cover layers that are glued to the honeycomb edges. The Honeycombs themselves are made by cutting off a honeycomb block won. In this sandwich network, the connection is the Honeycomb edges with the top layers are critical, which is why relatively thick layers of adhesive for embedding the Honeycomb edges used and the viscosity of the adhesive closely monitored.

Honeycombs cut from the honeycomb block are in limited adaptability to curved surfaces, however thus deformed honeycombs show internal tensions that in themselves are undesirable.

The invention has for its object a Specify folded honeycomb from a plurality of cells that in can be designed to be load-bearing, the shape of the flat layer can deviate, and the connection surfaces for Offers top layers if you consider the honeycomb as Wants to use sandwich core layer.

The task is due to the measures of Claims resolved.

Externally, the new folding honeycomb differs from the folded honeycomb cut from the block in that the rows of cells alternately from one side or the other Bridging parts are bridged. This Bridging parts connect the cell walls in one piece  with each other and provide additional stiffening of the Folded honeycomb across the cell walls. The surfaces of the Bridging parts can also serve as pads be used when the folding honeycomb is in a Sandwich construction is included.

The bridging parts are in the flat body by cuts and if necessary by folding lines delimited. It is possible to make U-shaped cuts place and the rag formed thereby in whole or in part to use as pads.

It is also possible to use wedge-shaped honeycombs or generally produce with height profile. The stripe-shaped Parts are getting wider and narrower made, and the boundary cuts of the strip-shaped Areas are curved or along route curves executed.

Before the touching wave crests and Wave sinks of the half honeycomb waves permanently with each other connected, it is possible to fold the honeycomb in itself move or distort, if necessary to adapt to curved surfaces. This form will then by establishing the permanent connection of the wave crests and wave sinks frozen to a certain extent. In this way bowl-like folded honeycombs can be produced have a certain self-bearing capacity. Such folded honeycombs can be processed into sandwich structure molded parts the honeycomb can also be used in crash Structures.

The flat body is used to manufacture the folded honeycomb with cuts and folded, what by a Rolling process is feasible. Is inexpensive to manufacture therefore to be expected. With ordinary paper or cardboard as A folding honeycomb is therefore used as the starting material considered as packaging material.

Embodiments of the invention are based on the Drawing described. It shows  

Fig. 1 shows a first planar body with fold lines and cutouts,

Fig. 2 is an intermediate state in the production,

Fig. 3 is a folded honeycomb,

Fig. 4 shows a second sheet body with folding lines and cuts,

Fig. 5 is an enlarged portion of a folded honeycomb, which has been produced from the material of Fig. 4,

Fig. 6 shows a modified folded honeycomb in an enlarged perspective view,

Fig. 7 is an enlarged perspective view of another folded honeycomb from abgewandeltem material of Fig. 6,

Fig. 8 shows a further embodiment of a planar body with folding lines and cuts,

Fig. 9 is an enlarged perspective view of a folded honeycomb, formed from the material of Fig. 8,

Fig. 10 shows a blank for curved honeycombs and

Fig. 11 is a perspective view of a curved folded honeycomb.

The folded honeycombs according to the invention are made of planes or flat bodies, for example thin Sheet metal, plastic film, fabric, sheet-like Chamfer composite (with carbon, aramid or glass fibers) or fiber-reinforced paper (Nomex® paper), but it will also consider normal paper or cardboard. The flat material is provided with cuts and serves then as the starting material for the folding.

Fig. 1 shows a flat path with periods of horizontal fold lines 1 , 2 , 3 , 4 and periods of vertical fold lines 5 , 6 , 7 , 8 . The folds can be prepared by embossing lines. Between the fold lines 2 and 3 and 4 and 1 , cuts 9 are made which cut out a rectangular area in the case of FIG. 1. The cuts 9 can run slightly in the direction along a vertical plane, the shaft sinks 22 a and 22 b touch each other, and a row 23 of hexagonal honeycombs is formed, as they correspond to the top row in FIG. 3. With this folding, the bridging parts 16 are simultaneously bent back into the horizontal about the folding line 4 , and the half honeycomb shaft with the part 22 d is folded so that the half honeycomb waves are vertical, the surfaces 22 c and 22 d then touching and being permanently connected to one another can be. This creates the second row 24 of cells in FIG. 3, which is offset from the first row 23 , as is the case with honeycomb structures.

As a result, the folded honeycomb structure of FIG. 3, which is provided with bridging parts, was created by folding wave structures in directions perpendicular to one another, which promises simple manufacture because this can be done by rolling.

Fig. 4 shows an embodiment of a blank with U-shaped cuts 9. As a result, flaps are formed which are divided into two flap regions 14 , 15 and 17 , 18 by the fold line 7 and 5 , respectively. The other features correspond to the embodiment according to FIG. 1. The flap region 14 is bent downwards and the flap region 15 is placed horizontally, while the flap region 17 is bent upwards and the flap region 18 is also placed horizontally. After folding in two different directions, as described with reference to FIGS. 2 and 3, the flap regions 14 and 17 become respective transverse webs which penetrate the respective cells 23 and 24 , and the flap regions 15 and 18 become connecting surfaces, which spanning the respective cells 23 , 24 , as indicated in FIG. 5. The tab areas 15 and 18 offer additional connection surfaces for a possible sandwich cover layer.

Fig. 6 shows another way of shaping the folded honeycomb. The starting material again has U-shaped cuts 9 , but the flaps of the fold lines 5 and 8 or 6 and 7 formed thereby will be extended. Such cuts can be made by punching.

Between the fold lines 2 and 3 , an interrupted strip 20 is formed which, in addition to the cuts 9 already mentioned, also contains bridging parts 13 , and between the fold lines 4 and 1 an interrupted strip 21 is formed which, in addition to the incisions 9, also contains bridging regions 16 . Continuous strip-shaped areas 22 , which are interspersed with the periodic fold lines 5 , 6 , 7 and 8 , lie between the strips 20 and 21 . As can be seen, the strip-shaped regions 22 are connected to one another via the bridging parts 13 and 16 , so that the material provided for folding consists of a coherent flat body.

The flat body of FIG. 1 can be folded in two mutually perpendicular directions, namely the square wave can be generated, the strips 20 21 the troughs and the strips 22 form the peaks, the strip, the corrugation flanks. The corrugation in the direction perpendicular thereto is achieved by partially folding around the fold lines 5 to 8 , which is referred to here as "pleating". Trapezoidal waves are generated, which are referred to here as "half-honeycomb waves with wave crests and wave sinks".

Fig. 2 shows an enlarged section with half honeycomb waves of three strip-shaped regions 22. As can be seen, the material of FIG. 1 is pleated so that the bridging parts 13 are aligned with the shaft crests, while the bridging parts 16 are aligned with the shaft sinks.

In Fig. 2 two adjacent wave sinks with 22 a and 22 b and two adjacent wave crests with 22 c and 22 d are designated. If you now fold the half honeycomb shaft with part 22 a around the folding line 2 , so that the wave runs along a vertical plane, and fold the strip-shaped region with the part 22 b around the folding line 3 , so that the half honeycomb shaft also 14 and 17 not interrupted by fold lines. The flaps 14 and 17 are bent vertically upwards or downwards, which results in stiffening webs within the respective cells.

Fig. 7 shows a further possibility of designing the folded honeycomb, namely the tabs 14 , 17 are left in their respective plane 20 or 21 . With a corresponding length of the tabs 14 , 17 they adjoin the bridging parts 13 , 16 and can be glued to the edges of the cell walls 22 . If the tabs 14 , 17 are of corresponding length, it is also possible to hide the ends of the tabs 14 below the respective adjacent bridging parts 13 in order to achieve a natural cohesion. The same applies to the ends of the tabs 17 and the bridging parts 16 . Finally, it is also possible to attach the flaps 14 , 17 to their respective bridging parts 13 , 17 (by gluing or the like) in order to obtain a continuous cover layer which spans the cells and thus solidifies the honeycomb.

FIG. 8 shows a blank for a transition between cells of different heights in the honeycomb, specifically a region that tapers in a wedge shape, and FIG. 9 outlines such honeycombs. Since the strips 22 form the cell walls, the strips 22 have to become wider for taller cells. If the edges of the cell walls are to lie in the boundary surfaces 70 , 71 of the wedge shape, the height of the cell wall of each cell on the side of the wedge tip must be lower than on the side of the wedge extension. The respective width of the strips 22 is therefore variable - also locally, within the strips 22 - as can be seen in FIG. 8. The flaps 14 and 17 are used as additional cover strips, and their front free end 15 , 18 is inserted under the respective adjacent bridging part 13 and 16 , respectively. The blank of FIG. 8 contains some narrow punch waste 72 . It is of course also possible to shorten the tabs 14 , 17 at their respective free ends so that they just touch the bridging parts 13 , 16 after the production of the half-honeycomb shafts. It goes without saying that the flaps 14 , 17 can also be glued to the free edges of the cell walls, as is known for the top layers of sandwich structures.

While in the previous exemplary embodiments the regions 20 , 21 had a constant width, it is also possible to vary the width of these regions 20 , 21 , for example to make the regions 20 increasingly wider than the regions 21 ( FIG. 10). This creates a curvature of the honeycomb transversely to the direction of the strip ( FIG. 11), and the surface portions generated with the wave crest surfaces 20 span over the surfaces generated by the wave trough portions, as is desirable, for example, in the case of a wing profile on the wing nose.

To the manufacture of the folding honeycombs described is still add the following:

As a first step, flat material is fed in, whereby fold lines 1-8 can be embossed, but this is not absolutely necessary.

As a second step, the cuts 9 are made, for example by punching rolls.

As a third step, the continuous strip-shaped areas 22 are folded trapezoidally around the lines 5 , 6 , 7 , 8 , ie the half-honeycomb waves are produced with wave crests and wave sinks. The width of the material is shortened in the feed direction. Rollers with trapezoidal teeth on the top and bottom of the material are used, which interlock so that the half-honeycomb waves are created. In order to adapt the tool to different widths of the continuous strip-shaped regions 22 , it is possible to assemble the rollers from individual plug-in gears, which are driven by a common spline shaft.

In an intermediate step, activatable adhesive surfaces can be attached in the strips between the fold lines 6 and 7 and 8 and 5 , which make up the wave crests and wave sinks in FIG. 2.

The next step is the folding along the continuous folding lines 1 , 2 , 3 and 4 , square waves being produced, in the wave crests or wave troughs of which the connection surfaces 13 and 16 come to lie. In the context of the invention, approximate rectangular waves are also to be understood, as they arise in the production of honeycombs with changing honeycomb heights ( FIG. 9) or in the case of curved honeycombs ( FIG. 11).

The next step is to bend flaps 14 and 15 , if there are any and should be bent over.

As a last step, the wave crests or Wave sinks of the half honeycomb waves connected to each other, if such a connection is provided for the structure is. Adhesion is the most suitable type of connection, however, welding and soldering is also possible.

If the shaft crests or shaft sinks are not to be glued to one another, it is also possible to fasten the tabs 14 , 17 to the bridging parts, in order to ensure a certain cohesion of the honeycomb.

Before attaching the shaft crests or sinks to each other or the rag on the bridging parts the structure will be kept in the form that it is final supposed to accept. The honeycomb then picks up without internal tension For example, a shell shape that serves as the core layer for a sandwich structure has many uses.

Since the manufacturing process largely uses rollers works, low manufacturing costs can be expected. That is why the manufacture of packaging material made of cardboard or paper. Opposite the The new packaging material has a conventional corrugated cardboard better compressive strength and does not bend easily Bending loads. In addition, the job starts at Shock loads significantly larger, d. H. the suitability as  Damping material when transporting packaged goods improved.

When the folding honeycomb is deformed, there are many webs and Walls affected so that a large deformation energy can be included. The honeycomb is therefore suitable for many crash structures that involve energy consumption.

Claims (20)

1. Folded honeycomb, formed from a plurality of cells arranged in rows, with the following features:
the folded honeycomb is folded from a coherent, flat body;
the flat body is divided into continuous strip-shaped areas ( 22 ) and into interrupted strip-shaped areas ( 20 , 21 ), the interrupted strip-shaped areas ( 20 , 21 ) having cuts ( 9 ) and bridging parts ( 13 , 16 ) which form the continuous strip-shaped areas Connect areas ( 22 ) to one another;
the continuous strip-shaped areas ( 22 ) are pleated to form half-honeycomb waves with wave crests ( 22 c, 22 d) and wave sinks ( 22 a, 22 b);
Adjacent half honeycomb waves touch with their wave crests or wave sinks to form a row of cells each;
each bridging part ( 13 , 16 ) bridges an associated cell. 2. folding honeycomb according to claim 1, characterized in that the wave crests ( 22 c, 22 d) or the shaft sinks ( 22 a, 22 b) are permanently connected to one another. 3. folding honeycomb according to claim 1 or 2, characterized in that the folding distances of the continuous strip-shaped areas ( 22 ) are uniform and four folds ( 5 , 6 , 7 , 8 ) form a period. 4. Folded honeycomb according to claim 3, characterized in that the connection surfaces ( 13 , 16 ) on the interrupted strip-shaped areas ( 20 , 21 ) form periods corresponding to the folds ( 5 , 6 , 7 , 8 ) of the continuous strip-shaped areas ( 22 ). 5. folded honeycomb according to claim 4, characterized in that the cuts ( 9 ) in the interrupted strip-shaped areas ( 20 , 21 ) comprise three quarters of a period. 6. folding honeycomb according to claim 5, characterized in that the cuts ( 9 ) are rectangular. 7. folding honeycomb according to claim 5, characterized in that the cuts ( 9 ) are U-shaped and form tabs ( 14 , 17 ). 8. Folded honeycomb according to claim 7, characterized in that the tabs ( 14 , 17 ) remain in the wave region ( 20 ) or the wave trough plane ( 21 ). 9. Folded honeycomb according to claim 7, characterized in that the tabs ( 14 , 17 ) are folded out of their respective corrugated or trough plane. 10. Folded honeycomb according to claim 9, characterized in that the free ends ( 15 , 18 ) of the tabs ( 14 , 17 ) are folded into the local wave trough plane or wave region. 11. Folded honeycomb according to one of claims 1 to 10, characterized in that the strip width of the continuous strip-shaped regions ( 22 ) varies according to the desired local layer thickness of the folded honeycomb. 12. Folded honeycomb according to one of claims 1 to 11, characterized in that the strip width of the interrupted strip-shaped areas for the wave crests ( 20 ) and the wave troughs ( 21 ) are selected differently in order to give local curvatures of the folded honeycomb. 13. A method for producing a folded honeycomb with the following steps:
a flat body made of metal, plastic, fabric, fiber composite material, fiber-reinforced paper or ordinary paper or cardboard is provided;
the flat body is provided with cuts ( 9 ) to form continuous strip-shaped regions ( 22 ) and interrupted strip-shaped regions ( 20 , 21 ) which alternate with one another, the interrupted strip-shaped regions ( 20 , 21 ) bridging parts ( 13 , 16 ) which connect the continuous strip-shaped regions ( 22 ) to one another;
the strip-shaped areas are folded transversely to the strip direction to give half-honeycomb waves with wave crests and wave sinks;
the flat body folded in strip areas ( 22 ) is folded into rectangular waves along fold lines ( 1 , 2 , 3 , 4 ) which separate the strip-shaped areas ( 20 , 21 , 22 ), the bridging parts in the wave crests ( 20 ) or troughs ( 21 ) come to rest;
flat parts ( 22 a, 22 b, 22 c, 22 d; 14 , 17 ) are brought to rest with opposing flat parts ( 22 a, 22 b, 22 c, 22 d; 13 , 17 ). 14. The method according to claim 13, characterized in that it is in the applied flat parts to the wave crests ( 22 c, 22 d) and the shaft sinks ( 22 a, 22 b) of the half-honeycomb waves, which are firmly connected. 15. The method according to claim 13, characterized in that it is in the brought to rest flat parts to the bridging parts ( 13 , 16 ) and the ends of tabs ( 14 , 17 ) which are formed from the cuts ( 9 ), and that these adjacent parts are firmly connected. 16. The method according to claim 14 or 15, characterized in that the fixed connection by Glue is done. 17. The method according to claim 14 or 15, characterized in that the fixed connection by Soldering is done. 18. The method according to claim 14 or 15, characterized in that the fixed connection by Welding takes place. 19. Use of the honeycomb according to one of claims 1 to 12 as Packing material. 20. Use of the honeycomb according to one of claims 1 to 12 as Crash structure.