DE102013016659A1 - Process for the production of a form-active structure and a structural support structure - Google Patents

Abstract

The present invention relates to form-active structures (1) and methods for their preparation. According to the invention, these have a network structure (11) coated with concrete. The inventive form-active structure (1) is relatively easy to produce and thereby comparatively thin, lightweight and yet durable. In addition, this structure (1) can be easily manufactured at the place of use. As a result, shell structures become economical again, since they become more economical to produce. There are completely new structural properties of a hybrid removal of train and compressive loads. A possible buckling behavior of the shell (1) is prevented by the continuous network structure (11) as a spatially curved tension construction (form-active). Nevertheless, at the same time a removal of compressive forces on the shell (1). Finally, very wide spans with very thin shells (1) can be produced.

Description

The present invention relates to form-active structures and methods for their production, ie structures that remove loads on their form. These may be, for example, synclastic or anticlastic forms.

It is known to construct such structures made of concrete, wherein previously a formwork is constructed from a membrane that simulates the shape of the structure. For example, describe the WO 96/33324 and the DE 196 37 567 A1 Procedures in which inflatable synclastic forms are sprayed with concrete. These formwork forms can then be reused.

A disadvantage of these methods is that they are relatively cumbersome.

The object of the present invention is to provide form-active structures that are relatively easy to produce. In particular, these structures should be comparatively thin, light and yet durable. It would also be desirable if these structures could be easily manufactured at the point of use.

This object is achieved with the method according to the invention according to claim 1 and the inventive form-active supporting structure according to claim 10. Advantageous further developments are specified in the dependent subclaims.

The inventor has recognized that the task can surprisingly be solved by coating a network structure with concrete. This results in an intimate bond of the network structure with the concrete. The network structure forms a consistent test for the form-active structure. It is thus used with the network structure a lost formwork, which forms the form-active structure together with the applied concrete. The network structure used thus has such a shape, so that the desired shape of the form-active structure results after coating the network structure with concrete. This structure can be performed at desired load capacity with thicknesses in the range of 4 cm to 8 cm, while usually produced concrete shells must have minimum thicknesses of 10 cm with such resilience. The form-active structures according to the invention are thus lighter than conventional form-active structures made of concrete. In this case, these form-active structures according to the invention can be produced quickly and easily at the place of use.

The applied concrete swells through the mesh of the net structure. The concrete is preferably applied in layers (individual layers). The network structure needs no additional temporary support. All construction elements such as guy ropes can continue to exist and form load-bearing components of the final construction. The initially plastic concrete is removed as a weight from the network structure as a formative tensile-stressed structure.

The concrete is preferably sprayed on, whereby the production is considerably simplified, in particular easily made possible in several steps.

In the context of the present invention, "supporting structure" is understood to mean not only entire supporting structures but also structural parts. In this case, this structure can be used, inter alia, for roof, floor and wall structures.

In the context of the present invention, "network structure" means any regular or irregular structure in which openings (meshes) are surrounded by webs and thus separated from one another.

Advantageously, the network structure is coated in the prestressed state with concrete, since then bulges of the network structure and associated loss of form can be effectively prevented in the context of coating with the concrete. At the same time there is a change in the expansion behavior of the network structure, whereby an adaptation to the e-modulus of the concrete is effected. The network structure needs no further support, but forms a self-supporting lost formwork.

Particularly advantageously, the network structure has a synclastic or anticlastic or any other form deviating from a plane. This arbitrary freeforms for the form-active structure can be produced.

The form-active structure is particularly easy if the network structure comprises synthetic fibers, in particular PE, PP, glass fibers, carbon fibers or Kevlar.

If it is provided in this context that the network structure is coated, wherein the coating comprises in particular PVC, PTFE or silicone, then the form-active structure is particularly durable, as a "concrete" and thus damage to the network structure and thus damage the form-active structure is effectively prevented by the concrete.

It is particularly preferably provided that the network structure has a mesh size in the range of 1 to 20 mm, preferably 3 to 10, in particular 3 to 7 mm. Then there is an optimum for an intimate connection of the concrete with the network structure, whereby the concrete can easily be sprayed on without being lost too much after penetrating the network structure. Overall, the mesh size is adapted to the type of concrete, with particular attention to its graininess. For large mesh sizes, the adhesion of the concrete can be improved by widening webs.

Especially in this context, it is advantageous if the concrete is a fiber-reinforced concrete, wherein the fibers in particular comprise metal fibers, carbon fibers or glass fibers. Then the concrete combines particularly easily intimately with the network structure. The fibers allow gluing of the concrete during the coating until it hardens and digs into the network structure.

For additional proof of the form-active structure, a metal mesh can be provided, which is designed in particular as a diagonal network, which preferably has a flat equal distance to the network structure. Alternatively, a conventional Baustahlbewährung be provided.

If at least partially a rigid version of the network structure is provided, which in particular has rigid edge supports, wherein the edge supports are preferably profiles (for example metal profiles) into which a piping of the net structure is received, then the edges of the net structure can swing up during coating, in particular spraying the concrete are effectively damped, while the dimensional accuracy of the desired final shape is ensured.

If the network structure is coated on both sides with concrete, then the network structure as a lost formwork forms a particularly protected condition (fire protection) inside the formative structure. In this case, the probation can be arranged symmetrically in the middle, asymmetric or partially asymmetric, to achieve certain pressure capacity in dependence on static requirements.

Independent protection is claimed for the form-active supporting structure according to the invention, which has a network structure coated with concrete, the structure being produced in particular by the method according to the invention.

In the context of the present invention, all features of the invention can be easily combined with each other. In this case, features of the method according to the invention can also be used as features of the structure and vice versa.

Furthermore, independent protection is claimed for the inventive manufacturing method, when it is used for the production of surface structures or folding units. Similarly, protection is claimed for tensile structures or folded structures, which have a concrete-coated network structure.

The characteristics of the present invention and further advantages will be clarified below with reference to the description of a preferred embodiment. Here are purely schematic:

1 a shapely structure in a side view and

2 the form-active structure after 1 in a top view from above.

In the 1 and 2 is the form-active structure according to the invention 1 shown purely schematically in two different views. It can be seen that the structure 1 on three foundations 3 rests and by means of the guy ropes 5 with three other foundations 7 is tense. These are stiff edge beams 9 provided steel, which are formed as profile body and corresponding piping (not shown) of the network structure 11 take up. The further foundations 7 are visible in the ground 13 completely embedded while the foundations 3 from the soil 13 rise.

The network structure 11 consists of PVC-coated PE fibers and has a mesh size of 4 mm. On it was in several steps only on the top 13 then on the bottom 15 Steel fiber reinforced concrete was sprayed on. For simplified representation is in the 1 and 2 the concrete coating not shown. The concrete coating penetrates the network structure 11 and thus forms a close bond. Using the guy ropes 5 was such a bias on the network structure 11 transfer that bulging and giving way to the mesh structure 11 prevented during concrete spraying. The stiff edge beams 9 prevent the edges of the network structure from swinging up 11 effective during spraying.

In lieu of the depicted mesh structure 11 To produce other shapes, for example, particularly pointed ridge areas 13 , additional fillet or ridge ropes can be used, which could be removed again after hardening of the concrete.

The fact that the concrete during hardening intimately with the network structure 11 an effect is created, as it is known from prestressed concrete constructions. The bias of network structure 11 also produces a particularly high stability during the curing of the concrete coating, which is ensured when the concrete coating is intimately connected to the network structure 11 connects, so both network structure 11 as well as concrete coating together the form-active structure 1 form and are no longer or only with difficulty separable from each other.

This form-active structure 1 So is a composite material that can absorb locally both compressive forces, shear forces and bending moments, in conjunction with a building form which allows optimal load transfer of normal forces, ie tensile or compressive forces, due to their form finding as a pure train construction. Whether the structure reacts more than a tensile structure with a minimized change in shape or as a pressure-stressed shell depends on the degree of stiffening. Local bulging is prevented by the introduced and over the stiffening "frozen" bias. Likewise, the introduction of single loads is made possible without a serious change in shape or in "punching the construction" occurs. Destroying the formative structure by means of a simple tool becomes "reinforced stiffening" by the network structure 11 prevented.

After hardening of the concrete coating, the form-active structure 1 be processed in a conventional manner, for example, be provided with dowels or other fasteners for extensions or attachments. In addition, recesses can be made for windows and doors, which are then used in a conventional manner in these recesses.

In addition, during the application of the concrete coating can be another probation over the network structure 11 in any case, until hardening of the concrete in the direction of the tensile stress of the network structure 11 is kept taut and with which the concrete coating also intimately connects. This creates an additional "prestressed concrete effect". To produce a balanced thickness, this probation should be at a constant area distance from the network structure 11 be held, for example by means of numerous spacers (not shown).

Whether after the curing process, the mechanical bias of the network structure 11 is retained or removed depends on whether a "stiffened tensile structure" or completely converted to the shell construction is sought. In most cases, the bias will be maintained as part of a hybrid responsive structural support, or to guard against buckling or failure of the shell. In principle, however, it is also possible to remove the bias after the network structure 11 intimately connected to the concrete.

From the above illustration it has become clear that the inventive form-active structure 1 is relatively easy to produce and is comparatively thin, lightweight and yet durable. In addition, this structure can be 1 easy to make at the place of use.

With the inventive form-active structure 1 Shell structures are again economical because they are more economical to produce. There are completely new structural properties of a hybrid removal of train and compressive loads. A possible buckling behavior of the shell 1 becomes through the continuous polyester net 11 as spatially curved tensile structure (form-active) prevented. Nevertheless, at the same time there is a removal of compressive forces on the shell 1 , After all, there are very wide spans with very thin shells 1 produced.

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

• WO 96/33324 [0002]
• DE 19637567 A1 [0002]

Claims (10)

Method for producing a form-active structure ( 1 ), characterized in that a network structure ( 11 ) coated with concrete, wherein the concrete is preferably sprayed on. Method according to claim 1, characterized in that the network structure ( 11 ) is coated in the prestressed state and / or as a synclastic or anticlastic form with concrete. Method according to claim 1 or 2, characterized in that the network structure ( 11 ) Comprises synthetic fibers, in particular PE, PP, glass fibers, carbon fibers or Kevlar. Method according to one of the preceding claims, characterized in that the network structure ( 11 ), wherein the coating comprises in particular PVC, PTFE or silicone. Method according to one of the preceding claims, characterized in that the network structure ( 11 ) has a mesh size in the range of 1 to 20 mm, preferably 3 to 10, in particular 3 to 7 mm. Method according to one of the preceding claims, characterized in that the concrete is a fiber-reinforced concrete, wherein the fibers in particular comprise metal fibers, carbon fibers or glass fibers. Method according to one of the preceding claims, characterized in that an additional probation from a metal network, in particular a diagonal network is provided which preferably has a flat equidistant from the network structure. Method according to one of the preceding claims, characterized in that at least partially a rigid version of the network structure ( 11 ) is provided, in particular the stiff edge support ( 9 ), wherein the edge supports ( 9 ) are preferably profiles, in which a piping of the network structure is added. Method according to one of the preceding claims, characterized in that the network structure ( 11 ) is coated on both sides with concrete. Form-active structure ( 1 ), characterized in that it comprises a concrete-coated network structure ( 11 ), wherein the form-active structure ( 1 ) was produced in particular according to one of the preceding claims.

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