DE19936152C1 - Composite body for construction work consists of plate shaped elements fixed at join points and possessing outward bulges near contact points - Google Patents

Abstract

The composite body (10) consists of several, preferably two parallel plate-shaped elements (11,12) fixed firmly together by join-points (16). At least one of the plate-shaped elements has a number of bulging parts (14) pointing towards an adjacent plate-shaped element. The outward-bulges define the distance between the two adjacent plate-shaped elements. The join points are situated at least at some contact points between the adjacent plate-shaped elements near the bulges.

Description

The invention relates to a composite body, in particular for the high or Civil engineering consisting of several, preferably two, i. w. parallel to each other extending, plate-shaped elements is constructed, which means Enforcement points are firmly connected.  

The clinching technique for producing such composite bodies is general known, for example from the article by H. P. Liebig and R. Wieck with the title "H-pressure joining leads to joining elements with improved load-bearing behavior" in the Journal "Bänder Bleche Rohr" 3, 1989, pages 32-37 or from the article by L. Budde "Well combined" in the magazine "kleben & dichten ADHÄSION", vintage 40, 1-2 / 96, pages 44 to 47.

Push-through joining (= self-riveting) is a forming technique joining in Usually thin-walled sheet metal and profile parts by pushing through in Connection with cutting or countersinking at the joint and subsequent Cold upsetting, so that by width or extrusion a positive and positive Connection arises.

As the principle diagrams in FIGS. 5a-c show, two sheets of ductile materials are deformed by the punch and die of a tool in such a way that one forms a type of push button at the connection point and the other forms the associated cup-like recess into which the " Push button "is engaged.

The advantages of this technique are that there is no extra connecting element is needed and at least when pushing through without a cutting part Material breakthrough occurs. This makes the connection point unlike many other joining techniques such as screws and rivets in the joining direction absolutely tight and provides no starting point for the penetration of unwanted, e.g. B. Corrosive media. Comparatively tight connections are obtained otherwise only by welding, soldering and gluing.

The clinching technique, often referred to as pressure joining technique, is this The term is actually broader and also includes rivets. Construction for the connection of metal profiles and the fastening of reinforcements, Straps, tabs and small sheet metal parts have proven their worth. The production of large areas Hollow bodies must be considered "technical malpractice" in this branch, since they only parts connected at the edge via flanges are generally not sufficiently and bulge proof and because of the side joints u. a. are susceptible to corrosion. Because the components are as smooth as possible because of the look  have to be manufactured, come through sheet metal bulges stabilized and Joining points distributed over the entire surface are out of the question.

Hollow plates as such are known from sandwich engineering. Your cavities are however, through the mostly honeycomb-shaped support body in small plots divided and therefore not functionally fillable and hardly deformable.

The mainly used connection technology for the sheets and the Support body is gluing. However, this usually leads to heat-sensitive and basically flammable products that are limited in construction or cannot be used at all.

In the building industry there are some rules that apply e.g. In contrast to general technology and especially to car construction:

• - Lightweight construction requirements do not always apply. B. hollow Provide base plates with (also heavy) functional fillings and can be used as facade panels.
• - In many versions, the sealing of the large areas against this Penetration of moisture and other harmful media is particularly important. The side joints must be in the case of panel-shaped components anyway normally be sealed.
• - Open hollow panels made of corrosion-resistant material can also be used here Find the use at any time a pressure, humidity and Allow temperature compensation and thereby the unwanted Pressure change effect of encapsulated cavities in operational Exclude temperature fluctuations.
• - In building construction panels, optically specially trained Joining points often remain visible or even from architectural-optical Reasons.

The object of the present invention is therefore to provide a composite body of the beginning to introduce the type described, as a hollow structure for the building industry is designed to be producible with only the simplest possible means and the above described, existing requirements in construction such as strength of the Structure, pressure and moisture tightness of the connection points and possibility of Filling with functional media as far as possible.

According to the invention, this object is achieved in that at least one of the plate-shaped elements a plurality of against an adjacent plate-shaped Element directed bulges that the bulges one Define the distance between the two adjacent plate-shaped elements from one another, and that at least at some points of contact of the adjacent plate-shaped Enforcement points are provided in the area of the bulges.

The fastening of the adjacent plate-shaped elements to one another by means of Enforcement is much easier and less labor intensive than, for example Rivets or screws and can also be fully automated, for example by a Manufacturing robots. The strength of the assertive association at least as large if not larger than at other fastening methods, such as bonding with organic and / or inorganic binders or setting connection points with mechanical fasteners such as screws, rivets or clamps. On in this way, relatively little effort is required for civil engineering, particularly suitable as a facade panel or wall element with functional filling Hollow structure. Because of the clinching technique used according to the invention the composite body can be made absolutely fluid-tight, because the Enforcement points no breakthrough through the plate-shaped elements produce.

Depending on the optical and architectural requirements as well as the The desired stiffness and strength of the composite body can be as many as desired Connection points using clinching technology at the corresponding Contact points of the bulges with the neighboring one plate-shaped element can be set.  

The composite body according to the invention can be such that it has a good quality Adhesion base for attaching a desired top layer results. Moreover can the knobs of the clinching points and bulges if they are attached on the visible side to the composite body according to the invention, as decorative Serve patterns.

In general, the composite body according to the invention can be used for the respective Application can be optimally modified by adapting the Material parameters, material combination of inner and outer plate-shaped Elements, in particular ductility and rigidity of the materials used, Plate spacing by appropriate arrangement of the bulges and shape, Size, number and location of the enforcement points.

The composite body according to the invention can have a wide variety of geometries getting produced. An embodiment in which only one is particularly simple of the two adjacent plate-shaped elements against the other plate-shaped Element has directed bulges. The other plate-shaped element can, for example, only be a flat sheet.

Significantly more design options exist for embodiments of the Composite body according to the invention, in which both adjacent plate-shaped Elements directed against the other plate-shaped element Bulges have:

In a development of this embodiment, the height h of the bulges, thus the maximum extent of the bulges from the respective one plate-shaped element away, in the two adjacent plate-shaped Elements of the same size, which considerably simplifies and reduces the cost of production.

A further development is characterized in that the bulges Touch the adjacent plate-shaped element at a point where the adjacent plate-shaped element has no bulges, and that the Distance between the two adjacent plate-shaped elements equal to each other  Height h of the bulges is. The bulges are thus "offset" arranged, which is a hollow structure with a small thickness and particularly high Stiffness results.

Alternatively, the composite body according to the invention can also be designed such that the bulges the adjacent plate-shaped element at one point touch where the adjacent plate-shaped element also has a bulge and that the distance between the two adjacent plate-shaped elements from each other is equal to the sum of 2 h of the heights of the bulges. Thereby the cavities of the composite body with the same total weight of the used plate-shaped elements with a significantly larger volume equipped and the thickness of the composite body twice as large.

Another embodiment of the composite body according to the invention is characterized in that the heights h ₁ , h _{2 of} the bulges, that is to say the respective maximum extent of a bulge away from the corresponding plate-shaped element, are of different sizes in the two adjacent plate-shaped elements, and in that the bulges touch the adjacent plate-shaped element at a point where the adjacent plate-shaped element also has a bulge. By appropriately adapting the heights h ₁ and h ₂ , any plate thicknesses and volumes of the resulting hollow structure can be represented.

Here, too, there are a wide variety of possibilities for designing the geometry of the composite body according to the invention. The two most important developments of the above embodiment consist in the fact that one of the two adjacent plate-shaped elements only has bulges of height h ₁ , the other only bulges of height h ₂ , or alternatively that both adjacent plate-shaped elements each have bulges of height h ₁ as well Have bulges of height h ₂ , and that the two adjacent plate-shaped elements only touch at locations where one plate-shaped element has a bulge of height h ₁ and the other has a bulge of height h ₂ .

Another embodiment of the invention is particularly preferred Composite body, in which at least one of the plate-shaped elements Bulges on one side and bulges on the other Has side of the plate-shaped element, with this on each side plate-shaped element by means of an adjacent plate-shaped element Enforcement points are firmly connected to this plate-shaped element. In order to honeycomb structures of the hollow structure can be made from almost any generate geometric arrangement.

It is also conceivable that when using plate-shaped elements Bulges on both sides one side an outside of the represents composite body according to the invention and for example as a spacer for constructions to be assembled on the composite body according to the invention acts.

Depending on the area of application of the composite body according to the invention, the Bulges of the plate-shaped elements have different shapes. Bulges in the form of are particularly easy to manufacture Spherical caps or truncated cones.

In other embodiments, the bulges are plate-shaped Elements of the composite body according to the invention designed channel-shaped.

Similar to, for example, corrugated iron, this can be used in further developments Embodiment at least part of the trough-shaped bulges in parallel run to each other, resulting in a particularly high bending stiffness of the Composite body around an axis perpendicular to the channels and an elevated Bendability around an axis parallel to the channels results.

A configuration is also possible in which at least part of the channel-shaped Bulges at an angle, preferably a right angle, too other trough-shaped bulges. This gives you a special one large area moment of inertia and an extremely high bending stiffness of the emerging hollow structure.  

Especially for the preferred applications in the field of civil engineering it is of great advantage if the plate-shaped elements are made of high temperature resistant and / or non-flammable materials are constructed.

In addition, the choice of materials allows an extremely wide range of properties in the composite according to the invention:

In embodiments, the plate-shaped elements can be made of non- metallic materials, in particular from inorganic materials or from permanently deformable plastic. As another possibility of The choice of material also includes glass, for example.

Furthermore, the materials of the plate-shaped elements fibers, Have fabric layers and / or networks, which in particular leads to a high The load-bearing capacity and strength of the composite body built from it contributes.

Alternatively or additionally, the plate-shaped elements can also include metallic materials or be constructed entirely from them.

In the simplest case, the plate-shaped elements are constructed from sheet metal for which the clinching technique is particularly suitable and tested.

The plate-shaped elements can, however, in other embodiments also be constructed from ductile metal mesh, which corresponds to them Gives properties in terms of strength and flexibility.

An embodiment of the invention is also particularly preferred Composite body in which between adjacent plate-shaped elements Reinforcement layers made of metallic and / or non-metallic materials, in particular nets, waffle plates, fiber or fabric layers are arranged, which further increase the strength and load-bearing capacity of the composite body.  

To ensure a secure hold of the reinforcement layers within the To achieve composite body-formed hollow structure are in further training this embodiment, the reinforcement layers from the clinching points, that connect the two adjacent plate-shaped elements.

With regard to the various uses of the composite body according to the invention in the construction sector are between particularly preferred embodiments neighboring plate-shaped elements fillings with functional substances, such as for example incombustible and / or heat-storing and / or heat-conducting liquids, heat, sound and / or moisture insulation materials, radiation absorbing materials and / or stiffening fillers intended. In particular, the filling materials can be equipped so that a Crumbling of the filling is prevented and also in the case of cracks in the filling resulting stiffening effect is largely retained.

The assembly of such a filled hollow plate, for example on a Building facade is preferably carried out so that an open filling gap after shows above in order to facilitate the filling of the filling material if the filling of the Hollow plate should only be inserted on the facade after installation. This also facilitates transportation and assembly itself.

In a further particularly preferred embodiment of the invention Composite body are lines between adjacent plate-shaped elements, in particular pipelines for fluids and / or electrical lines, cables and the like provided. These can be used as facade panels or Composite bodies designed as wall elements as finished functional groups in the Construction.

A further development of this embodiment is particularly advantageous, in which the Lines between the plate-shaped elements with a solidifying, preferably non-flammable filler are poured.

Furthermore, it is of great advantage if at least one surface of the Composite body connection points are provided for the lines.  

In particular, for use in building and / or civil engineering purposes composite body according to the invention in the form of a plate.

However, the composite body according to the invention does not necessarily have to be one represent closed area, but can also be used as a frame if necessary be trained.

Likewise, the composite body according to the invention can have cutouts for windows, Doors, solar cells, lamps, etc.

In a further embodiment of the invention, the composite body is used as a support and / or support structure for building construction elements, in particular for Facade panels trained.

A method for producing the Composite body described above, which is characterized in that by Deform, especially by deep drawing or punching bulges in the plate-shaped elements are removed, that two plate-shaped Elements are placed on top of each other, and that in the area of the contact points of some bulges with the adjacent plate-shaped element Enforcement points are set.

The enforcement points can be in the contact area of the bulges two adjacent plate-shaped elements or in areas in between provided the bulges of both adjacent plate-shaped elements have the same height h.

A method for processing the invention is particularly preferred Composite body, in which the cavities between adjacent plate-shaped Elements with preferably pourable and / or flowable filling material, especially with functional materials such as concrete, mortar, plastic, inorganic Adhesive, metal, glass and / or with non-flammable and / or heat-storing and / or heat-conducting fluids and / or filled with recycling materials,  preferably be poured out. For this it is beneficial if at least beforehand one of the plate-shaped elements by folding at the edges of the Composite body is closed on three sides, so that a tight cavity arises, into which the filling material can be let in through a filling opening.

A method variant can be advantageous in which the material to be filled remains free-flowing and / or flowable.

Alternatively, process variants can be used, which are characterized by distinguish that the filling material solidifies after filling the cavities, and that after filling and before solidifying the filler Composite body is deformed, for example bent or folded. In turn alternatively, the method can be carried out in such a way that the Filling material solidifies after filling the cavities, and that after the Solidifying the filling material of the composite body deformed, for example bent or is folded, the filling material being deliberately in the area of deformation is broken.

A method variant in which ductile support cores, especially from soft material, into the cavities between neighboring ones plate-shaped elements are inserted and the composite body is then deformed. The support cores can, for example Soft material exist and facilitate the damage-free deformation of the composite body according to the invention.

In a preferred method variant, the support cores are after Deform the composite body again from the cavities between adjacent ones plate-shaped elements removed so that they can be reused several times can.

In other applications, however, it can also be advantageous if the support cores after deforming the composite body in the cavities between adjacent plate-shaped elements remain.  

Further advantages of the invention result from the description and the Drawing. Likewise, the above and the others According to the invention, the features listed individually in each case or in several any combination can be used. The ones shown and described Embodiments are not to be understood as a final list, but rather rather have exemplary character for the description of the invention.

The invention is illustrated in the drawing and is based on Exemplary embodiments explained in more detail. Show it:

Figure 1 is a schematic cross section through an embodiment of the composite body according to the invention, wherein said only one of the two adjacent plate-shaped elements against the other plate-shaped member directed bulges.

Having 2 shows an embodiment in which the two adjacent plate-shaped elements directed towards each other bulges, wherein the bulges touch the adjacent plate-shaped element respectively at a position between its bulges.

FIG. 3a shows an embodiment with the same bulge height h of the two adjacent plate-shaped members, wherein the bulges of the adjacent plate-shaped elements contact each other;

FIG. 3b as Fig 3a, but with different heights h _1, h ₂ of the bulges in one and in the other plate-like element.

FIG. 3c as shown in Figure 3b, but with bulge heights h _1, h ₂ are each plate-shaped in both elements.

FIG. 3d like FIG. 3a, but with a reinforcement layer between the two adjacent plate-shaped elements;

Figure 4a comprises an embodiment with a plate-shaped member, the bulges on both sides and having respective flat plates than adjacent elements.

FIG. 4b as shown in Fig 4a, but with plate-shaped elements as neighbors, each of which has bulges themselves. and

Fig. 5a-c the work sequence in clinching according to the prior art without cutting portion in a schematic representation.

A particularly simple embodiment of the composite body 10 according to the invention is shown in schematic cross section in FIG. 1: A plate-shaped element 11 , which in the present example is essentially flat, butts with conical bulges 14 against a plate-shaped element 12 which runs parallel thereto and is also essentially flat. The distance h between the two adjacent plate-shaped elements 11 , 12 defines the height h of the bulges 14 . At the points of contact of the bulges 14 with the adjacent plate-shaped element 12 , the two plate-shaped elements 11 , 12 are firmly connected to one another by means of clinching points 16 .

In the embodiment of a composite body 20 according to the invention shown in FIG. 2, the two adjacent plate-shaped elements 21 , 22 each have bulges 14 and 15 , respectively, which touch the respectively adjacent element at locations where it does not have bulges and there firmly by means of clinching points 16 adjacent plate-shaped element are connected. In this case too, there is a distance between the adjacent plate-shaped elements 21 , 22 in the size of the height h of the bulges 14 , 15 .

FIGS . 3a to 3d show embodiments in which the two adjacent plate-shaped elements each have bulges which touch the bulges of the respectively adjacent element, the push-through joining points 16 being attached in the contact region for the fixed connection of the adjacent plate-shaped elements.

In Fig. 3a, the composite body 30 a has two adjacent plate-shaped elements 31 a, 32 a, the bulges 14 , 15 each have the same height h, so that there is a total distance of the adjacent elements 31 a and 32 a of 2 h.

In Fig. 3b, the composite body has 30 b two adjacent plate-shaped members 31 b and 32 b, with the protuberances 34 of the plate-shaped member 31 b, respectively, the height h ₁ and the bulges 35 of the plate-shaped member 32 b, respectively h ₂ having the height so that there is a total distance of the adjacent plate-shaped elements 31 b and 32 b of h ₁ + h ₂ .

The composite body 30 c in FIG. 3 c has two adjacent plate-shaped elements 31 c, 32 c, both of which both have bulges 34 , 34 'of height h ₁ and bulges 35 , 35 ' of height h ₂ . Again, there is a total distance between the adjacent plate-shaped elements 31 c and 32 c of h ₁ + h ₂ , but the penetration joining points 16 are not in one plane, as in the case of the composite body 30 b in FIG. ₃ b, but in different planes.

The composite element 30 d in Fig. 3d has the basic structure as the composite element 30 a in Fig. 3a, but between the adjacent plate-shaped elements 31 d and 32 d, a reinforcing layer 37 is provided, which from the clinching points 16 , which the adjacent plate-shaped elements Connect 31 d and 32 d, is interspersed.

In Fig. 4a, a composite body 40 is shown in a, a has a plate-shaped member 41 and has on both sides bulges 44 45. Flat plates 42 a, 43 a are provided as adjacent plate-shaped elements, which are connected to the plate-shaped element 41 a via the clinching points 16 .

FIG. 4b shows a variant in which the laminated body b 40 is also a plate-shaped member 41 b with bulges 44, 45 having, however, in contrast to the composite body 40 a shown in Fig. 4a bulges 14 and 15 of the adjacent plate-shaped members 42 b, 43 b meet. In this way, a honeycomb-like cross section of the composite body 40 b is created.

In FIGS. 5a-5c, finally, the operation sequence is illustrated schematically in the clinching of the prior art, in which no cutting portion is to occur. The two adjacent plate-shaped elements 51 , 52 are pressed in the area of their contact by a punch 58 against a die 59 , which creates a clinching point 56 . Due to the special shape of the die 59 , when the material of the plate-shaped elements 51 , 52 flows when pressed by the stamp 58, a shape is formed which has a kind of "push button" in the plate-shaped element 51 and a matching "cup-like depression" in the adjacent plate-shaped one Element 52 results, wherein the "push button" is firmly engaged in the "cup-like" recess.

Claims (41)

1.Composite body ( 10 ; 20 ; 30 a; 30 b; 30 c; 30 d; 40 a; 40 b), in particular for building or civil engineering, which consists of several, preferably two, preferably parallel, plate-shaped elements ( 11 , 12 ; 21 , 22 ; 31 a, 32 a; 31 b; 32 b; 31 c, 32 c; 31 d, 32 d; 41 a, 42 a, 43 a; 41 b, 43 b) which are firmly connected to one another by means of clinching points ( 16 ), characterized in that
that at least one of the plate-shaped elements ( 11 ; 21 , 22 ; 31 a, 32 a; 31 b, 32 b; 31 c, 32 c; 31 d, 32 d; 41 a; 41 b, 42 b, 42 b, 43 b) has a plurality of bulges ( 14 ; 15 ; 34 , 35 ; 34 ', 35 '; 44 , 45 ) directed against an adjacent plate-shaped element such that the bulges define a distance between the two adjacent plate-shaped elements,
and that at least some points of contact of the adjacent plate-shaped elements in the region of the bulges have penetration points ( 16 ). 2. Composite body according to claim 1, characterized in that only one ( 11 ; 41 a) of the two adjacent plate-shaped elements ( 11 , 12 ; 41 a, 42 a, 43 a) against the other plate-shaped element ( 12 ; 42 a, 43 a) has directed bulges ( 14 ; 44 , 45 ). 3. Composite body according to claim 1, characterized in that both adjacent plate-shaped elements ( 21 , 22 ; 31 a, 32 a; 31 b, 32 b; 31 c, 32 c; 31 d, 32 d; 41 b, 42 b, 43 b) have bulges ( 14 , 15 ; 34 , 35 ; 34 ', 35 '; 44 , 45 ) directed towards the other plate-shaped element. 4. Composite body according to claim 3, characterized in that the height h of the bulges ( 14 , 15 ; 44 , 45 ), ie the maximum extent of the bulges ( 14 , 15 ; 44 , 45 ) of the respective plate-shaped element ( 11 , 12th ; 21 , 22 ; 31 a, 32 a; 31 d, 32 d; 41 b, 42 b, 43 b) away, is the same size for the two adjacent plate-shaped elements. 5. Composite body according to claim 4, characterized in that the bulges ( 14 , 15 ) touch the adjacent plate-shaped element ( 22 , 21 ) in each case at a point where the adjacent plate-shaped element has no bulge, and that the distance between the two adjacent plate-shaped Elements ( 21 , 22 ) from each other are equal to the height h of the bulges ( 14 , 15 ). 6. Composite body according to claim 4, characterized in that the bulges ( 14 , 15 ; 44 , 15 ; 45 , 14 ) touch the adjacent plate-shaped element ( 32 a, 31 a; 32 d, 31 d) at a point where the adjacent plate-shaped element also has a bulge, and that the distance between the two adjacent plate-shaped elements ( 31 a, 32 a; 31 d, 32 d) from one another is equal to the sum of 2 h of the heights of the bulges ( 14 , 15 ; 44 , 45 ) is. 7. Composite body according to claim 3, characterized in that the heights h ₁ , h _{2 of} the bulges ( 34 , 35 ; 35 ', 34 '), ie the respective maximum extent of a bulge away from the corresponding plate-shaped element, in the two adjacent ones plate-shaped elements ( 31 b, 32 b; 31 c, 32 c) are of different sizes, and that the bulges ( 34 , 35 ; 35 ', 34 ') the adjacent plate-shaped element ( 32 b, 31 b; 32 c, 31 c ) touch each at a point where the adjacent plate-shaped element also has a bulge ( 35 , 34 ; 34 ', 35 '). 8. Composite body according to claim 7, characterized in that one ( 31 b) of the two adjacent plate-shaped elements exclusively bulges ( 34 ) of height h ₁ , the other ( 32 b) exclusively bulges ( 35 ) of height h ₂ . 9. Composite body according to claim 7, characterized in that both adjacent plate-shaped elements ( 31 c, 32 c) each have bulges ( 34 , 34 ') of height h ₁ and bulges ( 35 ', 35 ) of height h ₂ , and that the two adjacent plate-shaped elements ( 31 c, 32 c) only touch at locations where one plate-shaped element has a bulge of height h ₁ and the other has a bulge of height h ₂ . 10. Composite body according to one of the preceding claims, characterized in that at least one of the plate-shaped elements ( 41 a; 41 b) both bulges ( 44 ) on one side and bulges ( 45 ) on the other side of the plate-shaped element ( 41 a ; 41 b) has, and that on each side of this plate-shaped element ( 41 a; 41 b) each have an adjacent plate-shaped element ( 42 a, 43 a; 42 b, 43 b) by means of clinching points ( 16 ) with this plate-shaped element connected is. 11. Composite body according to one of the preceding claims, characterized in that the bulges are frustoconical. 12. Composite body according to one of claims 1 to 10, characterized characterized in that the bulges take the form of Have spherical caps.   13. Composite body according to one of claims 1 to 10, characterized characterized in that the bulges are trough-shaped. 14. Composite body according to claim 13, characterized in that at least part of the trough-shaped bulges parallel runs to each other. 15. Composite body according to claim 13 or 14, characterized in that at least part of the trough-shaped bulges underneath an angle, preferably a right angle, to others trough-shaped bulges. 16. Composite body according to one of the preceding claims, characterized in that the plate-shaped elements high temperature resistant and / or non-flammable materials are built up. 17. Composite body according to one of the preceding claims, characterized in that the plate-shaped elements non-metallic materials are constructed. 18. Composite body according to claim 17, characterized in that the plate-shaped elements made of inorganic materials are built up. 19. Composite body according to claim 17, characterized in that the plate-shaped elements made of permanently deformable plastic are built up. 20. Composite body according to one of claims 1 to 16, characterized characterized in that the plate-shaped elements made of metallic Materials are built up.   21. Composite body according to claim 20, characterized in that the plate-shaped elements are constructed from sheet metal. 22. Composite body according to claim 20, characterized in that the plate-shaped elements made of ductile metal mesh are. 23. Composite body according to one of the preceding claims, characterized in that between adjacent plate-shaped elements ( 31 d, 32 d) reinforcing layers ( 37 ) made of metallic and / or non-metallic materials, in particular nets, waffle sheets, fiber or fabric layers are arranged. 24. Composite body according to claim 23, characterized in that the reinforcing layers ( 37 ) are penetrated by the clinching points ( 16 ) which connect the two adjacent plate-shaped elements ( 31 d, 32 d). 25. Composite body according to one of the preceding claims, characterized in that between neighboring plate-shaped elements fillings with functional materials, such as for example incombustible and / or heat-storing and / or heat-conducting liquids, heat, sound and / or Moisture insulation materials, radiation absorbing materials and / or stiffening filling materials are provided. 26. Composite body according to one of the preceding claims, characterized in that between neighboring plate-shaped elements lines, in particular pipes for fluids and / or electrical lines, cables and the like are provided.   27. Composite body according to claim 26, characterized in that the Lines between the plate-shaped elements with one yourself solidifying, preferably non-flammable filler poured are. 28. Composite body according to claim 26 or 27, characterized in that that on at least one surface of the composite body Connection points for the lines are provided. 29. Composite body according to one of the preceding claims, characterized in that the composite body in the form of a Plate is formed. 30. Composite body according to one of the preceding claims, characterized in that the composite body as a frame is trained. 31. Composite body according to one of the preceding claims, characterized in that the composite body recesses for Has windows, doors, solar cells, lamps, etc. 32. Composite body according to one of the preceding claims, characterized in that the composite body as a support and / or support structure for building construction elements, in particular is designed for facade panels. 33. A method for producing a composite body ( 10 ; 20 ; 30 a; 30 b; 30 c; 30 d; 40 a; 40 b) according to one of the preceding claims, characterized in that bulges (by deformation, in particular by deep drawing or punching) 14 ; 15 ; 34 , 35 ; 34 ', 35 '; 44 , 45 ) in the plate-shaped elements ( 11 ; 21 , 22 ; 31 a, 32 a; 31 b, 32 b; 31 c, 32 c; 31 d, 32 d; 41 a; 41 b, 42 b, 43 b) are attached so that two plate-shaped elements are placed one on top of the other, and that in the area of the contact points of some bulges with the adjacent plate-shaped element enforcement points ( 16 ) are set. 34. The method according to claim 33, characterized in that the clinching points ( 16 ) are set in the contact area of the bulges of two adjacent plate-shaped elements. 35. The method according to any one of claims 33 or 34, characterized characterized in that the cavities between adjacent plate-shaped elements with preferably free-flowing and / or flowable filling material, in particular with functional substances such as Concrete, mortar, plastic, inorganic adhesive, metal, glass and / or with non-flammable and / or heat-storing and / or heat-conducting fluids and / or filled with recycling materials, preferably be poured out. 36. The method according to claim 35, characterized in that the Filling material remains free-flowing and / or flowable. 37. The method according to claim 35, characterized in that the Filling material solidifies after filling the cavities, and that after filling and before solidifying the filling material the composite body is deformed, for example bent or is folded. 38. The method according to claim 35, characterized in that the Filling material solidifies after filling the cavities, and that after the solidification of the filler the composite body deformed, for example bent or folded, the Filling material is broken in the area of the deformation.   39. The method according to any one of claims 33 to 36, characterized characterized in that ductile support cores, in particular Soft material, into the cavities between neighboring ones plate-shaped elements are inserted and the Composite body is then deformed. 40. The method according to claim 39, characterized in that the Support cores again after deforming the composite body the cavities between adjacent plate-shaped Elements are removed. 41. The method according to claim 39, characterized in that the Support cores after deforming the composite body in the Cavities between adjacent plate-shaped elements remain.