DE20210915U1 - Membrane-covered support structure - Google Patents

Description

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Utility model application Lars Meeß-Ohlson

Kamperstr. 1 D-42555 Velbert-Langenberg

Membrane-covered supporting structure

Technical area

The innovation concerns a three-dimensional supporting structure for a building construction containing

a frame (14) consisting of at least three pressure elements, e.g. rods (16), wherein the pressure elements do not directly touch each other,
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a rope-like tension structure which is connected to the frame,

at least one membrane provided on the rope-like tension structure.

State of the art

Such three-dimensional support structures for building constructions are used in many different ways, for example in tents, especially circus tents. The tent often consists of at least one pressure element, which is often designed as a vertical rod, which is held in the vertical position with ropes. Depending on the size, two or more rods are used. This rod and rope-like tension structure is ultimately used to

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a tarpaulin is laid. The tarpaulin is attached at certain points and stretched to the ground with ropes to enclose the space. The statics of such structures are only maintained via the frame-rope construction. The tarpaulin, on the other hand, only has a covering function. The tent construction is dependent on the static cooperation of the ground and does not represent a self-contained balance of forces.

Self-supporting works of art are also known in which at least one membrane is attached and stretched to a frame. In these works of art, the frame, which consists of several rods, is stretched statically using ropes. In these works of art, the membranes only have a surface-covering function and are not necessary from a static point of view.

Roofs, domes, towers and similar usable building structures are known which consist of a frame, with the gaps filled with glass panes, for example. The frame used for this purpose must have a high load-bearing capacity, as the glass panes place a great deal of weight on the frame. In such cases, the frames are therefore either made of expensive material, such as aluminum, or are very large and thus potentially unsightly. If the frames are corpulent, they often take up large areas and must be additionally supported due to their high weight. In addition, these building structures are often braced with complex rope structures in order to give the structure the necessary statics.

The disadvantage of the above-mentioned state of the art is that the building structures have to be stabilized using additional components, since there is no balance of forces in the supporting structure itself and it only has limited static stability of its own. A further disadvantage is that the building structures are difficult to transport due to their own weight and their bulky construction.

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The aim of the innovation is therefore to avoid the disadvantages of the state of the art and to create a supporting structure for a building construction that is inexpensive and easy to manufacture. Furthermore, the aim of the innovation is to produce a supporting structure with individual parts that are as small as possible.

According to the innovation, the object is achieved in that, in a supporting structure for a building construction of the type mentioned at the beginning, the membrane is prestressed on the rope-like tension structure for supporting the building construction, whereby ropes of the rope-like tension structure form the edge for the membrane.

The innovation is based on the principle of maintaining the system-immanent tensile and compressive forces, which are necessary for the statics of such a structure, via the membrane as the primary component. By tensioning the membrane appropriately, such a structure becomes stable and can be used in a variety of ways. Due to their low weight, such support structures for building constructions are easy to transport. Such constructions are therefore particularly suitable for temporary use. They can be easily assembled and dismantled. Lightweight constructions, such as those proposed here, can also be used well for aerospace. Since the construction essentially consists of membranes and cables as well as individual pressure elements, it can be easily dismantled and packed up compactly. When the support structure is created, a statically reliable structure is obtained.

It has proven to be an advantageous embodiment of the innovation if the membrane is stretched between at least two cables. To stretch the membrane, at least two tension sides are necessary, which is achieved here by two opposing pieces of cable. The cables are attached to the frame for this purpose.

In a further advantageous embodiment of the innovation, elastic and/or inelastic rods are integrated into the rope-like tension structure. This measure also makes it possible to create shapes that are desirable for the design of certain building structures. The membrane can also be stretched over such a rod. However, according to the innovation, the edge of the membrane is held by ropes. Advantageously, the rope-like tension structure itself is rigid. This simplifies assembly and also achieves an even more stable statics for such an innovative support structure.

The membrane is designed to be translucent so that such a support structure can also be used as a room, e.g. for living, and/or a greenhouse. Depending on the environment in which the support structure is set up, it can be advantageous for the membrane to be multi-layered. The multi-layered structure serves in particular to increase the tear resistance of the membrane. Where temperatures are too high or too low, the membrane of an innovative support structure for a building construction can advantageously be designed to be insulating. In this context, a light-reflecting layer on the membrane is suitable, which, for example, does not let the sun's rays through and prevents the corresponding other side from heating up.

One aspect of the innovation is that the supporting structure for a building construction is now designed as a dome. Alternatively, it is possible to design a supporting structure as a roof or wall. A curved flat construction with a pressure or tension ring as well as a tower-shaped building construction can also be created in a suitable manner, each in a closed or partially open form.

In another suitable embodiment of the innovation, the membrane is designed to be permeable or semi-permeable. This allows a targeted gas exchange to be induced between the two membrane sides.

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In a further development of the innovation, the building construction consists of several membrane elements assembled in a mosaic-like manner.

Further advantages arise from the subject matter of the subclaims.

Short description of the drawing

Fig. 1 shows a schematic diagram of a first embodiment of a

innovative support structure for a semi-open polyhedron as

Building construction.

Fig. 2 shows a schematic diagram of a second embodiment of a

innovative supporting structure for a closed polyhedron as a building construction.

Fig. 3 shows a schematic diagram of a third embodiment of a

innovative supporting structure for a closed, arched

Construction with pressure ring.
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Fig. 4 shows a schematic diagram of a fourth embodiment of a

innovative supporting structure for a partially open arched

Construction with pressure ring.

Fig. 5 shows a schematic diagram of a fifth embodiment of a

innovative supporting structure for a closed, arched construction with tension ring.

Fig. 6 shows a schematic diagram of a sixth embodiment of a

innovative supporting structure for a closed tower-like

B oor construction.

Fig. 7 shows a schematic diagram of a seventh embodiment of a

innovative supporting structure for a partially open tower-like building construction.

Preferred examples

In Fig. 1, 10 denotes a building construction. In the present embodiment, the building construction 10 is referred to in three-dimensional representation as a semi-open polyhedron. The building construction 10 has a supporting structure 12.

This support structure 12 contains a frame 14. The frame 14 is made up of rods 16. A rope-like tension structure 18 is provided on the frame 14, which is also considered part of the support structure 12. The rope-like tension structure 18 is tensioned by means of membranes 20. In this case, ropes 22 of the rope-like tension structure 18 completely form the edge of the membranes 20. This gives the building structure 10 its static stability. The membranes 20 do not cover all conceivable outer surfaces of the polyhedron, so that the building structure 10 is half open to the outside.

The second embodiment, which is shown in Fig. 2, basically corresponds to that of Fig. 1. Identical components of the construction are therefore also designated with corresponding reference numerals. In this embodiment, however, all conceivable outer surfaces, which are formed by the rope-like tension structure 18, are covered by the membranes 20. This creates a closed hollow body. The frame 14, which was still visible in Fig. 1, is now covered.

Another geometric shape for a building construction 10 is shown three-dimensionally in Fig. 3 and 4. Fig. 3 shows a closed construction and Fig. 4 a partially curved construction with a pressure ring. This support structure 12 of the two embodiments has, as previously described in the previous figures, a frame 14 consisting of rods 16, to which the rope-like tension structure 18

is provided. The cables 22 of the cable-like tension structure 18 point approximately radially outwards and are attached to a ring structure 24 as a pressure ring. The cable-like tension structure 18 is in turn tensioned with membranes, which makes the structure statically stable. The cables 22 form the edges of the membranes 20. In Fig. 3, all outward-facing surfaces formed by the cables 22 of the cable-like tension structure 18 are tensioned and covered with the membranes 20. In the curved structure with pressure ring of Fig. 4, the covering by the membranes 20 only occurs partially, so that a partially open curved structure is created. The frame 14 is completely covered by the membranes 20 in Fig. 3. In Fig. 4, however, it can be seen because it is only partially covered by the membranes 20.

The embodiment of Fig. 5 shows, analogously to the previous examples, a support structure according to the innovation, which is designed as a curved construction with a pull ring. Corresponding components are therefore designated with the same reference numerals.

A further variant of the innovation results from the tower construction, as shown in Figures 6 and 7. In these exemplary embodiments, the building construction 10 has a supporting structure 12, which can only be seen in Figure 7. This supporting structure 12 contains a frame 14 as before. The frame 14 is made up of rods 16. A rope-like tension structure 18 is provided on the frame 14. Here too, the rope-like tension structure 18 is tensioned by means of the membranes 20. The cables 22 of the rope-like tension structure 18 completely form the edge of the membranes 20. This gives the building construction 10 its static stability. In Figure 6, the membranes 20 cover all conceivable outer surfaces of the tower, so that the building construction 10 is closed to the outside. In Figure 7, these surfaces are only partially covered, so that the body appears half open. In these embodiments too, the membranes 20 tension the cables 22 of the cable-like tension structure 18, so that the structure becomes statically stable.

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The membranes 20 can be designed in different ways in the above-mentioned embodiments. For example, they can be multi-layered, translucent, reflective or insulating. The type of membranes 20 can vary depending on the application requirements.

Claims (16)

1. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) comprising - a frame ( 14 ) consisting of at least three pressure elements, e.g. rods ( 16 ), wherein the pressure elements do not directly touch each other, - a rope-like tension structure ( 18 ) which is connected to the frame ( 14 ), - at least one membrane ( 20 ) provided on the rope-like tension structure ( 18 ), characterized in that
the membrane ( 20 ) is prestressed on the rope-like tension structure ( 18 ) for supporting the building structure ( 10 ), wherein ropes ( 22 ) of the rope-like tension structure ( 18 ) form the edge for the membrane ( 20 ). 2. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to claim 1, characterized in that the membrane ( 20 ) is stretched at least between two cables ( 22 ). 3. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to one of claims 1 or 2, characterized in that elastic and/or inelastic rods ( 16 ) are integrated into the rope-like tension structure ( 18 ). 4. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to one of claims 1 to 3, characterized in that the rope-like tension structure ( 18 ) has a rigidity. 5. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to one of claims 1 to 4, characterized in that the membrane ( 20 ) is designed to be translucent. 6. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to one of claims 1 to 5, characterized in that the membrane ( 20 ) is multi-layered. 7. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to one of claims 1 to 6, characterized in that the membrane ( 20 ) is designed to be insulating. 8. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to one of claims 1 to 7, characterized in that the membrane ( 20 ) is designed to reflect light. 9. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to one of claims 1 to 8, characterized in that the building construction ( 10 ) is designed as a flat or curved construction with a tension ring. 10. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to one of claims 1 to 9, characterized in that the building construction ( 10 ) is designed as a roof or wall. 11. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to one of claims 1 to 10, characterized in that the building construction ( 10 ) is designed as a flat or curved construction with a pressure ring. 12. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to claim 11, characterized in that the flat or curved construction with a pressure ring is provided as a building construction ( 10 ), partially open or substantially closed. 13. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to one of claims 1 to 10, characterized in that the building construction ( 10 ) is tower-shaped. 14. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to claim 13, characterized in that the tower-shaped building construction ( 10 ) is provided open or closed. 15. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to one of claims 1 to 14, characterized in that the membrane ( 20 ) is permeable or semi-permeable. 16. Three-dimensional support structure ( 12 ) for a building construction ( 10 ) according to one of the preceding claims, characterized in that the building construction ( 10 ) consists of several membrane elements ( 20 ) assembled in a mosaic-like manner.