DE19633319A1 - Self-supporting wall construction e.g. for large industrial cooling towers - Google Patents

Abstract

The self-supporting wall construction includes a flat internal wall shell (2) and an outer wall shell (3) are connected over connecting elements (4). The wall shells (2, 3) and the connecting elements (4) are formed from modular, prefabricated components (5). The components are preferably formed as disk-shaped modules which are arranged horizontally side by side in rows, and a number of rows are arranged vertically, one on the other. The connecting elements are preferably formed as vertically proceeding, disk-shaped modules which are arranged vertically to the wall shells.

Description

The invention relates to a self-supporting wall construction for buildings, especially for large tower constructions.

Below tall tower structures, such are as high as buildings Buildings understood, which essentially consist of a self-supporting Outer shell, d. H. Outside wall exist. These include, for example Industrial chimneys, cooling towers - especially natural draft cooling towers for Power plants and chemical plants - as well as radio and other towers as well larger, hall-like buildings, as they are often used in industrial and also Sports facilities can be found.

According to the prior art, it is common for self-supporting walls for such On-site purposes, d. H. on the construction site from appropriate materials manufacture. To ensure safe static properties, the Walls for such tower structures have previously been cast from reinforced concrete. This construction has the advantage that by a corresponding Dimensioning the wall thickness and the reinforcement with fibers or Monier iron, definable and predictable static properties are reachable.

At the same time, this approach also brings a number of Disadvantages with it: The walls can only in sections be pulled up, with the assembly of a Scaffolding and formwork is absolutely necessary. This design  involves a considerable amount of work, which u. a. too long too Construction times. Of course, this triggers considerable costs. The cost of materials also contributes to this, as does the size of the building Ensuring adequate static safety disproportionately increases.

Due to the required use of materials, such a structure has Build up a relatively large net weight. This is how a larger natural draft cool weighs tower of known design up to 70,000 t. It goes without saying that also the building foundation must be able to withstand these loads, what requires a correspondingly high amount of material and work and high Brings costs.

The object of the invention is therefore to solve the aforementioned Problems, in particular to reduce the material and time required and the Reduce costs. On the other hand, none of the static properties Cutbacks are made.

To achieve this object, the invention proposes that a flat inner wall shell and an outer wall shell via connecting elements are connected by a distance, the wall shells and the Connecting elements made of modular, prefabricated components be formed.

According to the presently massive wall construction by two Flat wall shells arranged at a distance replaced. These are in essentially statically equivalent and fixed using fasteners connected with each other.

The special advantages arise on the one hand from the fact that the Material use is significantly less than with solid construction. Next lower costs, this also results in an order of magnitude lower total weight of the building. That means that too Foundation can only be designed for a lower load than before  got to. Due to this fact, material and costs are again saved.

Other advantages result from the fact that the entire wall construction including the wall shells and their connecting elements modular components are assembled, which are industrial can be prefabricated. Through these measures according to the invention the erection of the walls is made considerably easier because no scaffolding or other support measures are required. Because it is simply possible Piece by piece further modular components to the finished, in to add self-supporting wall structures to every stage of construction, until the building is completed.

The individual components can be particularly economical in all produce the required shapes and dimensions industrially. Thereby the actual construction of the buildings is restricted, d. H. of the Wall constructions, ready to be put together on the construction site delivered modules. Are suitable for connecting them to each other connection methods familiar to the prior art, for example Screwing, riveting, gluing or the like. Overall requires a wall construction according to the invention considerably less time, material and workload. The costs decrease accordingly.

The prefabricated components are expediently in the form of plates Modules trained. Such plates can be easily made Assemble flat or curved wall shells of any size. she enable particularly efficient production and are also simple can be connected to one another, for example by screw connections or others Fasteners. Like the wall bowls, they can Fasteners be plate-shaped. These are then between the both wall shells inserted vertically and connected to them. Such built wall constructions are characterized by their good static Properties, d. H. their high stability, from.  

For the construction of a large building, it is particularly advantageous that the plate-shaped modules arranged horizontally next to each other in rows are and a plurality of rows are arranged vertically one above the other. This design allows a particularly efficient way of working Implement: First, a horizontal row of plate-shaped modules erected, which are already self-supporting. This row is in the same The next row is set up without any scaffolding or other support devices would be required. Be the same way the modules are assembled until the building is completed.

In view of favorable static properties, it is appropriate that the Fasteners as vertical, perpendicular to the Plate-shaped modules arranged in wall shells are formed. Thereby the wall construction receives a special one with regard to the vertical Bending stiffness. The vertical connecting plates are favorably arranged one above the other so that they are together with the wall shells form vertical channels. This will make the wall construction better statically controllable and allows the use of others Stabilization measures, which will be discussed below.

In this context, it is particularly advantageous that the outer Wall shell has openings. Conveniently, the Openings in the upper area of a building, for example a tower, attached and each open a passage from the outside to Space between the wall panels. Now has an effect in the upper area Wind load from the outside on the wall construction, the following effect occurs: Due to the dynamic pressure present there on the outer wall surface, the is higher than near the ground, the opening between the inner air and pressed outer wall shell. Through this overpressure, the through the wind load on fasteners relieved of pressure. It so to a certain extent there is a self-stabilizing effect, namely depending on the current wind load.

It is obvious that through this to some extent dynamic Stabilization of the wall construction using the previous one  Wall structures of more harmful wind pressure a second time Reduction in the amount of material required can be achieved.

The aforementioned effect is particularly well exploited if the Openings in each between the wall shells and the Connecting elements formed, vertical channels are arranged. Because of the flow resistance in these channels is higher, a particularly good one occurs due to the dynamic pressure Stabilizing effect. You could say that when you queue up Wind load with vertical air pressure Stabilizing elements are formed.

Air deflection devices are preferably arranged in the openings, which are embedded between the two wall shells. This allows the an airflow entering the openings due to the wind back pressure Flow direction between the wall shells or in the between the Wall shells formed channels can be specified. This is it particularly favorable that the air deflecting flow guide plates which have an air flow entering laterally into an opening Introduce between the wall shells at the bottom. The advantages of this Arrangement become clear when you consider that usually in higher altitudes there is a higher wind speed and therefore one greater wind load on the outer wall shell and thus a higher one Back pressure at the openings than in the lower areas. So far the air introduced in the upper areas moves a stabilization, For example, a tower-like building, over the entire height.

It is particularly advantageous that the prefabricated components Plastic. The plate-shaped modules are then the simplest Case plastic plates that can be connected together. These can be Manufacture particularly easily and inexpensively and in any shape and assemble dimensions. Furthermore, they are resistant and durable.  

The prefabricated components preferably consist of a fiber reinforced material. Such materials are characterized by a particularly high strength. The construction can accordingly turn out to be particularly light yet robust.

A fiber-reinforced is preferred for these prefabricated components Plastic used. In this regard, glass fiber reinforced are exemplary Plastics (GRP), carbon fiber reinforced plastics or with others Understand reinforcement fibers provided natural or artificial resins.

Particular advantages result from the fact that the invention Wall construction the wall of a cooling tower, especially a natural draft cooling forms towers. Such cooling towers are buildings considerable size, which among other things is also due to this is that the building materials used so far due to their static Properties did not allow smaller designs. Because of their size they offer the wind a significant area of attack thus far a correspondingly high amount of material was required. By the invention With such cooling towers the possibility is created for the first time, modern to use fiber-reinforced plastics. That way you can Reduce your own weight by a factor of 100.

In particular by the stabilization according to the invention by means of openings in the upper area of the outer wall shell and the vertical channels between the two wall shells can be another Realize an effect that is beneficial in several ways: By between the wall shells, directed through the openings vertical channels in the lower area that can be filled with air Interior of the tower formed from the wall shells will be introduced an overpressure is generated in the interior of the tower itself, which is another Stabilization of the structure causes. In addition, the flow accelerated so that the thermal efficiency of the cooling tower is increased at the same time. Calculations in this context shown that this increase in effectiveness further Material savings are possible.  

Embodiments of the invention are in the following with reference to the drawing explained in more detail. It show in detail

Figure 1 is a perspective, schematic representation of the wall structure of a cooling tower.

FIG. 2 shows a schematic detailed view of the wall construction from FIG. 1;

FIG. 3 shows a further detailed view of the wall construction from FIG. 1 in another representation;

FIG. 4 shows a vertical section through the wall construction according to FIG. 1;

Fig. 5 is a section AA of FIG. 4.

In Fig. 1, the wall structure of a cooling tower, for example a natural draft cooling tower, is shown in the construction according to the invention in a schematic network view and is provided as a whole with the reference number 1 . The dimensions of a cooling tower shown can in reality be up to 100 m in diameter and up to 200 m in height.

The wall construction 1 consists of an inner wall shell 2 , which is surrounded by an outer wall shell 3 at a radial distance and is connected to it via connecting elements 4 .

Both the wall shells 2 , 3 and the connecting elements 4 are firmly connected to one another from individual plate-shaped modules 5 , for example GRP plates, by screwing, riveting, gluing or the like. The modules 5 of the wall shells 2 , 3 are each connected to one another to form axial rings, which in turn are arranged one above the other up to the total height of the wall construction 1 . The connecting elements 4 , which are also designed as modules 5 , are arranged as vertical, radially protruding plates one above the other between the wall shells 2 , 3 . In this way, continuous channels 6 are formed between the wall shells 2 , 3 between two adjacent rows of connecting elements 4 over the entire height. For example, by leaving out individual modules 5 , 3 openings 7 are created in the upper region of the outer wall shell. These are shown with dark hatching as an example.

FIG. 2 shows, in a perspective illustration similar to that in FIG. 1, four rings of plate-shaped modules 5 arranged vertically one above the other. The same reference numerals as in FIG. 1 are used therein.

The partial structure of the wall construction 1 , which is shown in FIG. 2, is self-supporting.

The further construction of the wall construction 1 takes place in that the modules 5 of the inner and outer wall shells 2 , 3 and the connecting elements 4 are arranged one after the other in the form of rings, as shown in FIG. 3, for example until a tower structure is completed and are firmly connected to one another will.

The arrangement of the plane perpendicular to the wall construction channels 6 arises particularly clearly in the vertical sectional view in Fig. 4. It can be seen from above perpendicularly through between the wall shells 2,3 down channels 6. In the openings 7 in the outer wall shell 3 in the upper region of the wall construction 1 , air baffles 8 are arranged as air deflection devices between the wall shells 2 , 3 . These deflect an air flow entering laterally into an opening 7 , directed downwards between the wall shells 2 , 3 by the wind pressure.

The radial arrangement of the channels 6 is clearly visible in FIG. 5, which is a sectional view AA through the tower. Fig. 4 shows.

The construction of a wall structure 1, for example according to FIG. 1, takes place particularly quickly and efficiently, since the individual plate-shaped modules for the construction of the wall shells 2 , 3 and the connecting elements 4 are delivered as prefabricated modules and only have to be joined together at the construction site via appropriate connections . The plate-shaped modules 5 are, for example, industrially produced GRP construction parts. These are characterized by high internal stability and long-term durability.

In the construction itself, it is particularly advantageous that partial structures, such as shown in FIG. 2, are already self-supporting and so stable that the further construction, ie the addition of further modules 5 , can take place without the need for scaffolding or similar auxiliary structures .

Particularly good static properties are achieved if 3 openings 7 are made in the upper wall shell 1 in the outer wall shell. Through this, when wind pressure is present, if necessary via air deflection devices, such as flow guide plates 8 , air under pressure can enter the channels 6 formed between the wall shells 2 , 3 and the connecting elements 4, which channels generate a certain static dynamic pressure and can escape again in the lower region . This configuration ensures that good static properties, ie high stability, are achieved despite a relatively light, material-saving construction. The particular advantage of the construction according to the invention is that the stability increases dynamically when the wind pressure is increased.

Further details of the invention emerge from the attached Description with calculations.

Claims (14)

1. Self-supporting wall structure for buildings, in particular for large towers, characterized in that a flat inner wall shell (2) and an outer wall shell (3) are connected via connecting elements (4) at a distance from each other, the wall shells (2,3) and the connecting elements ( 4 ) are formed from modular, prefabricated components ( 5 ). 2. Wall construction according to claim 1, characterized in that the components are designed as plate-shaped modules ( 5 ). 3. Wall structure according to claim 2, characterized in that the plate-shaped modules ( 5 ) are arranged horizontally next to one another in rows and a plurality of rows are arranged vertically one above the other. 4. Wall structure according to claim 1, characterized in that the connecting elements ( 4 ) are designed as vertically extending, substantially perpendicular to the wall shells arranged plate-shaped modules. 5. Wall construction according to claims 1 and 4, characterized in that the wall shells ( 2 , 3 ) and the connecting elements ( 4 ) form vertically extending channels ( 6 ). 6. Wall structure according to one or more of claims 1 to 5, characterized in that the prefabricated components ( 4 , 5 ) consist of plastic. 7. Wall structure according to one or more of claims 1 to 6, characterized in that the prefabricated components ( 4 , 5 ) consist of a fiber-reinforced material. 8. Wall construction according to claims 6 and 7, characterized in that the prefabricated components ( 4 , 5 ) consist of fiber-reinforced plastic. 9. Wall construction according to claim 1, characterized in that the outer wall shell ( 3 ) has openings ( 7 ). 10. Wall structure according to claim 9, characterized in that in the openings ( 7 ) air deflection devices ( 8 ) are arranged. 11. Wall construction according to claim 10, characterized in that the air deflection devices ( 8 ) are located between the wall shells ( 2 , 3 ). 12. Wall construction according to claim 10, characterized in that the air deflection devices ( 8 ) have curved flow guide plates which introduce a laterally entering air flow downwards between the wall shells ( 2 , 3 ). 13. Wall structure according to one or more of claims 1 to 12, characterized in that the wall structure ( 1 ) forms the wall of a cooling tower, in particular a natural draft cooling tower. 14. Wall construction according to one or more of claims 1 to 13, characterized in that the between the wall shells ( 2 , 3 ), through the openings ( 7 ) directed with air vertical channels ( 6 ) in the lower region into the interior of a formed from the wall shells ( 2 , 3 ) tower, in particular a natural draft cooling tower.