EP1512804A2 - Method for producing a wall of a construction - Google Patents

Abstract

A process for producing a wall, comprises applying a membrane to at least one point by pre-tensioning it. The membrane is coated with a stiffening material, which combines internally with the primary membrane during hardening. A further membrane is applied at a distance to the primary membrane, and the space between them is filled with a stiffening material, which contains a reinforcement.

Description

The invention relates to a method for producing the wall of a building according to Preamble of claim 1.

From the prior art it is known to build structural structures that are in the essential from a relatively thin membrane and possibly additional clamping or Consist of reinforcing elements. Known examples of such structures are Inflatable halls, as used for example for the roofing of swimming pools become. Here, a relatively thin membrane in the contact area with the Foundation structure airtight completed and "inflated" in the interior. The building will be stabilized by the increased air pressure inside, of course only as long as measures are taken to maintain that air pressure. In these Traglufhallen are so-called. Synclastic structures which essentially characterized in that their curvature over the entire surface in one Direction (synclastic) runs, in other words, balloon structures.

Furthermore, structural structures are known from the prior art in which membranes are curved in different directions in space, which is referred to as anticlastic or saddle-shaped structures. A well-known example of such a form is the roofing of the Olympic Stadium in Munich. All mechanically prestressed membrane constructions and cable net constructions can only remove occurring dead loads and traffic loads as tensile forces. For this reason, it is necessary to produce at each point of the membrane surface a spatially counter-curved surface, since only this condition allows a vector decomposition of the forces occurring in different directions to tensile forces only. In addition, such a shape can only be stabilized by being kept under constant pretension. Here, the permanent loads and the bias generate the shape of the building or component. To introduce the preload forces constant mechanical biasing elements are needed. These are integral parts of a membrane design, as they must constantly maintain the bias.
Non-permanent loads, such as snow or wind, can be removed from these structures by adapting the shape of the surface to the new load cases and re-establishing a state of equilibrium via this change in shape. This change in shape is dependent on the degree of bias. The higher the bias, the lower the change in shape and vice versa. All occurring forces within the prestressed membrane can be removed only by tensile forces and a corresponding change in shape. It could be recorded no pressure forces or even bending moments. Shearing forces are absorbed only to a very limited extent by the fabric stiffness of the textile material. Individual loads perpendicular to the surface can be absorbed only by strong local changes in shape, or punch through the component, resulting in damage or destruction.

The structure must therefore by a not insignificant change in its shape on the Load changes can react even under changed loads a new one To reach equilibrium state. This dynamic structure of the structure is often undesirable and leads to connection problems, especially when creating fixed space cells should be. In addition, such a structure has virtually no sound and Heat protection on. It does not serve as a permanent structure in which things or persons protected from the external influences can stop. The protection against intrusion foreign persons is low, there by means of a simple cutting tool (knife) a Penetration can be enabled.

There is therefore the task of a generic method for producing the wall of a building so that a protected, durable, stable, weather-resistant and the interior against environmental influences shielding building arises.

This problem is solved by the characterizing features of claim 1. Advantageous embodiments are the dependent claims.

An embodiment of the invention will be described in more detail below.

The inventive method differs from the cited prior art an already anticlastic curved membrane under bias substantially in that this membrane is in the prestressed state with a stiffening material is coated, which during the subsequent curing intimately with the first Membrane connects.

With this measure one goes the step from a strained membrane to a real one Structure, because the stiffening material quite the strength of a conventional wall of a Building can reach and have all the properties, which on the wall of a building Structure, in particular light protection, sound insulation, thermal and cold protection, the removal of loads etc .. It does not matter if the wall only the ceiling or the sidewalls comprises or dome-like (but always anticlastic) formed is.

It is important that the stiffening material during hardening intimately with the Membrane connects. As a result, an effect is generated, as he himself Prestressed concrete structures is known. In the practice of the present invention creates the bias of the membrane during curing of the overlying Stiffening material also a very high stability, which is then ensured when the stiffening material intimately bonds with the membrane, that is both membrane as well as stiffening material together form the wall and no more or only difficult to separate from each other. The result is a building or component, consisting of a Composite construction material that locally absorbs both compressive forces, shearing forces and bending moments Can, in conjunction with a building form the optimal load transfer of Normal forces, ie tensile or compressive forces, due to their form finding as pure Zugkonstruktion, allows. Whether the structure is more than a train construction with minimized Change in shape, or responds as a compressive shell, depends on the degree of Stiffening. Local bulging is introduced by the over and over the stiffening "frozen" pre-tension prevented. Likewise, the introduction of single loads allows without a serious change in shape or a "punching through the Construction. "Destroying the wall by means of a simple tool becomes prevented by the "reinforced stiffening".

As possible membranes for carrying out the method according to the invention can all Membranes are used, which are due to their material properties in the Construction technology have proven or can prove. In particular, you can Polyester membranes, steel or glass fiber membranes, ethyltetrafluoroethylene membranes etc. are used.

Possible reinforcing materials are fiber-reinforced polyester resins, wherein the reinforcement with plastic, aramid, carbon, glass fibers or with Steel fabric can be done. Furthermore, fiber-reinforced epoxy resins come into consideration where the reinforcement can also be made with the fibers and fabrics mentioned.

Another option instead of fibers or a fabric is the use of Expanded glass or expanded clay spheres or another inflated, stable material (Plastic, steel ...), which with the hardening material and the membrane a Verbund enters. The hardening material could also be an alternative to the mentioned glue or glue.

In addition, gypsum filler or plastic plaster comes into consideration.

The application of the stiffening material can be carried out in known methods be carried out, for example, by hand lamination, in the fiber spraying process, in Vacuum method, in the autoclave method, in the injection method, in the winding method, in Pressing process, in the pultrusion process and in the casting process, wherein the gypsum filler and The plastic plaster can also be applied in the spatula, spray, pumping and casting process can. The exact procedure of the described method is not closer since it is described in detail in the relevant literature.

The thickness of the stiffening layer can be from a few millimeters to a few decimeters vary, with conventional wall thicknesses of a structure come into consideration in particular.

After curing of the stiffening material, the wall in a conventional manner be processed, for example with dowels or other fasteners for Aufoder Attachments are provided. In addition, recesses can be used for windows and doors be made, which then used in a conventional manner in these recesses become.

In addition, during the application of the stiffening material in this one be arranged further probation, in any case, until the curing of the Stiffening material held stretched about in the direction of the tension of the membrane and with which the stiffening material also intimately connects. This creates a additional "prestressed concrete effect".

In a further embodiment, parallel and substantially equidistant to the first membrane another membrane may be arranged, which with the first membrane for example, is connected by spacers. Here then becomes the stiffening material placed in the space between the two membranes, z. B. by pumps, and combines intimately with these two membranes during the subsequent curing.

Whether after the curing process, the mechanical prestressing construction of the membrane retained or removed depends on whether a "stiffened tensile structure" or striving for shell-converted construction throughout. In most cases is the biasing structure as part of a hybrid-responsive structure, or to Retain protection against dents or failure of the shell. Basically exists but also the possibility to remove the clamping structure after the membrane intimately connected to the stiffening material.

Claims (7)

A method for producing the wall of a structure, wherein a first membrane which is anticlutically curved at at least one point and which approximately defines the shape of the wall is prestressed, characterized in that the first membrane is prestressed in the prestressed state with a stiffening material which during the subsequent curing intimately connects with the first membrane. Method according to one of the preceding claims, characterized in that a further membrane is arranged substantially equidistant from the first membrane, the stiffening material is introduced into the intermediate space between the two membranes and connects intimately to both membranes during the subsequent curing. Method according to one of the preceding claims, characterized in that a reinforcement is arranged in the stiffening material, which is held in any case stretched until hardening of the stiffening material in the direction of the tensile stress of the first membrane and with which the stiffening material intimately connects. Method according to one of the preceding claims, characterized in that the first membrane and optionally further membrane of the materials plastic, in particular polyester and ethyltetrafluoroethylene, glass fibers, metal or a combination of these materials is selected. Method according to one of the preceding claims, characterized in that the stiffening material is selected from the materials polyester resin, epoxy resin, plaster filler, plastic plaster. A method according to claim 5, characterized in that the stiffening material is fiber or fabric reinforced and the reinforcing fibers or fabrics are selected from the materials plastic, aramid, carbon, glass and steel. Method according to one of the preceding claims, characterized in that the stiffening material by hand lamination, filling, spraying, in particular fiber spraying, by vacuum, autoclave, injection, winding, compression, pultrusion, pumping, casting or in a combination of these methods is applied.