EP0131696A2 - Reinforcing structure for large containers - Google Patents

Abstract

Substantially cylindrical and relatively thin-walled large containers, such as silos, are supported on the inside by means of a support structure which is designed as a triangular support triangle and is firmly connected to the inside of the container wall. As a result, a substantial part of radial forces in the circumferential direction, i.e. Forces acting tangentially on the container wall are implemented, so that the risk of deformation is reduced if the force transmission elements, such as pipes inside the container, are connected to the support triangle.

Description

The invention relates to a support structure for substantially cylindrical and relatively thin-walled large containers such as silos, tanks, mixing containers, etc.

The rationalization requires in many areas of construction technology, agriculture, energy supply, warehousing, large-scale chemical production and the like. Large-capacity containers, which either serve for the storage or storage of filling material or are to be carried out within the process or production processes. If such large containers are filled evenly with filling material, the filling material forces are distributed relatively evenly over the essentially cylindrical outer wall, so that they are essentially only tangential, i.e. is exposed to forces acting in the circumferential direction and the container wall can also be made relatively thin-walled. Thin-walled containers cause less material costs and are also lighter than thick-walled, so that lower transport costs are incurred and a lower weight presses on the support surfaces of such large containers.

However, it has been shown that the container wall is to be made thick-walled when the forces acting on the container wall act unevenly. These problems occur particularly when inside the container Apply forces along power transmission units, for example pipes, to singular points or special points on the container wall and such forces are then no longer effective tangentially, but in particular radially. This risk of deformation also occurs when external forces attack the container wall unevenly. While one can eliminate such externally applied forces by additional supporting structures many times, which is at the respective crossing point of the forces to the vessel wall _- are arranged, preparing the modeling Ver danger from the inside by acting forces many problems.

The invention / is based on the object of providing a support structure for such large containers which, despite its simple construction and essentially problem-free assembly, prevents the risk of deformation of the large container. ;

The invention / is that in the interior of the container at least one triangular support triangle is arranged in the container cross-section perpendicular to the container axis, the ends of which are supported on the inside against the substantially cylindrical container wall and are in particular firmly connected thereto.

This "fixed connection" means such a connection between the support triangle and the container wall that the forces transmitted from the support triangle to the container wall are essentially tangential forces within the container wall; the "fixed connection" can theoretically also be understood as a kind of "pivot point", "hinge line" or "pivot point".

The support triangle therefore essentially has the task of converting the forces which occur unevenly within the container and in particular in the radial direction to deform, in particular bulge, of the container into such forces Forces which essentially only extend tangentially in the container wall, ie in the circumferential direction. Such a support triangle is easy to produce, for example by connecting three support struts which form an isosceles triangle and are connected to one another by their ends. The circumscribing point of intersection of these triangular ends corresponds approximately to the circle which is formed by the central plane of the container wall which is circular in cross section, so that when the support triangle is inserted into the container or when the container is pulled onto the support triangle, the container is practically not deformed. The triangular tips offset from one another in the container at an angle of approximately 120 ° prevent the container from denting at the relevant points, ie these triangles form an inward support there. If these triangular tips are not only loosely applied to the inner surface of the container wall, but are also firmly connected to the container wall, an even better transmission of force in the tangential direction of the container wall is achieved.

The support structure then represents the device on which the forces occurring unevenly in the interior of the container act; For example, pipes, if they transmit forces, are firmly connected to the support triangle, in particular by welding.

For many purposes, for example when several forces acting in different directions occur, it is advisable to combine two or even more such support triangles with one another. According to this particular embodiment of the invention / innovation, at least two support triangles are connected to one another in such a way that their ends are supported on the inside of the container wall - and are firmly connected to it - and that the support triangles are also firmly connected to one another in the vicinity of attack points of forces. By an appropriate choice of the angles between the parts of the support triangles that extend from such connection points to the container wall, an optimal balance of forces can be ensured; it is even possible to compensate for a large proportion of the forces acting in different directions within the support triangle combination, so that these forces do not have a full effect on the container wall.

Within the scope of the invention / it is also possible, however, to use the support triangle to absorb those forces which would be transmitted from outside the container to the container wall if there were no support triangle according to the invention / in accordance with the invention. For this purpose, the forces transmitted from the outside to the container wall are transmitted directly from the transfer point in the same direction through the container wall to the support triangle, which can be done, for example, by a force transmission element permanently installed between the relevant point of attack on the container wall and the support triangle.

• Fig. 1 eine schematische Außenaufsicht auf einen Behälter und eine darin befindliche Stützkonstruktion, bei der der Behälterdeckel abgenommen ist;
• Fig. 2 einen Querschnitt etwa entlang der Linien A-A von Fig. 1 und
• Fig. 3 einen entsprechenden Querschnitt durch eine andere Ausbildung der Erfindung/Neuerung unter Verwendung zweier Stützdreiecke.

The invention / is explained in more detail below with the aid of two particularly preferred exemplary embodiments. Show in the drawing

• Figure 1 is a schematic external view of a container and a support structure located therein, in which the container lid is removed.
• Fig. 2 shows a cross section approximately along the lines AA of Fig. 1 and
• Fig. 3 shows a corresponding cross section through another embodiment of the invention / innovation using two support triangles.

1, a support triangle 2 is inserted into the container 1, the ends 3 of which are supported evenly over the circumference on the inside of the container wall 1 and are additionally welded on the inside of the container wall 1 a by means of welded connections 4. The container wall 1 a is cylindrical and the cylinder axis corresponds to the container axis B. While the force transmission elements located inside the container, such as pipes, are not shown in this figure, it is clear that outer pipes 9 lead to the container 1 from the outside and are welded to the tank wall 1 a via welded connections.

According to FIG. 2 it is clear that the outer tubes 9, which exert radial forces P on the container wall 1 a, are to a certain extent connected to the support triangle 2 for power transmission by means of extensions, ie in the same axial direction as the axes of the outer tubes 9, namely via welded connections 8 . While the outer tube 9 shown at the bottom right in FIG. 2 continues through the adjoining tube 7, so that a flow connection between the outer tube 9 through the container wall 1 a and the tube 7 and also via the support strut 2 c into the interior inside of the support triangle 2 is possible, the tube 7 shown in FIG. 2 on the left, which forms the extension of the outer tube 9, bends downwards when the support strut 2a of the support triangle 2 is reached. Due to the welded connections 8, however, a good .force transmission and therefore equalization of the radial forces I is ensured, which are then transmitted to the container wall la due to the welded connections 4 of the ends 3 of the support triangle 2 in the form of tangential forces P _t , provided that some of the forces are not is even received by the third support strut 2b of the support triangle 2.

In contrast to previously known devices of this type, the welded connections 10 therefore no longer have to absorb all the forces which act in the radial direction of the container 1.

In Fig. 1, an axial force P _{a is also} shown schematically. Since such axial forces P _a practically do not contribute to a deformation of the container wall 1 a, no special support measures are generally required in this regard.

According to FIG. 3, a combination of two supporting triangles 2, 2 'which are firmly connected to one another is inserted into the container 1. These two support triangles 2, 2 "are offset from one another by an angle α such that their ends 3, at which the support struts are connected to one another by welded joints 5, are separated from one another at a distance A _U on the circumference of the container wall 1.

Here, too, there are welded connections 4 between these ends 3 of the support triangles 2, 2 'and the inside of the container wall 1 a. Within the container, for example, the schematically illustrated tube 7 transmits a first radial force P _r1 in the direction of the arrow shown to the two supporting triangles 2, 2 ', which at the relevant point of attack of the tube 7 not only via welded connections 8 to the tube 7, but also via welded connections 6 are firmly connected.

Correspondingly, welded connections 6 are present at the other force application points P _r2 'P _r3 between the support triangles 2, 2'.

In these exemplary embodiments, essentially no radial forces act on the container wall la via the outer tube 9, so that the outer tube 9 can end on the outer wall la and the weld connection 10 between the outer tube 9 and the container wall la has practically no radial forces to be transmitted.

It is recommended not only to produce the relatively thin-walled container wall, but also the support triangles from aluminum or an aluminum alloy.

Although welded connections are shown and described in the exemplary embodiments, other power transmission connections can also be used, for example rivets or screw connections, although welded connections have proven to be the most advantageous in most cases because of the rigidity.

The support triangle should be arranged in the container such that it transmits the forces essentially tangentially to the container wall; In this respect, the support triangle represents a force transmission element with an effect that changes the direction of the forces in the sense of reduced wall deformability.

Instead of the welded connections, other connecting members, e.g. Bolts, can be used.

Claims (14)

1. Support structure for essentially cylindrical and relatively thin-walled large containers, such as silos, tanks, mixing containers etc.,
characterized ,
that in the interior of the container (1) at least one triangular support triangle (2) is arranged in the container cross-section perpendicular to the container axis (B), the ends (3) of which are supported on the inside of the essentially cylindrical container wall (la) and with it in particular are firmly connected. 2. Support structure according to claim 1,
characterized ,
that the fixed connection between the ends (3) of the support triangle (2) and the container wall (la) consists of at least one welded connection (4). 3. Support structure according to claim 1 or 2,
characterized ,
that the support triangle (2) consists of support struts (2a, 2b, 2c) which are assembled into an approximately isosceles triangle such that the ends form the ends (3) of the support triangle (2). 4. Support structure according to claim 3,
characterized ,
that the abutting ends of the support struts (2a, 2b, 2c) are firmly connected by means of welded connections (5). 5. Support structure according to one of the preceding claims,
characterized ,
that at least two support triangles (2, 2 ') are connected to one another in such a way that their ends (3) are supported on the inside of the container wall (la) and that the support triangles (2, 2') are in the vicinity of points of application of forces (P) are also firmly connected to each other. 6. Support structure according to claim 5,
characterized ,
that the connection point near the points of attack are welded connections (6). 7. Support structure according to one of the preceding claims,
characterized ,
that tubes (7) located inside the container (1) are firmly connected to the support triangle (s) (2, 2 '). B. support structure according to claim 7,
characterized ,
that the fixed connections consist of welded connections (8). 9. Support structure according to one of the preceding claims,
characterized ,
that are supported from outside the container (1) to the container wall (la) or through these through the outer tubes (9) on the support triangle (2, 2 '). 10. Support structure according to claim 9,
characterized ,
that the outer tubes (9) with the container wall (la) and / or the support triangle (2, 2 ') are connected by welded connections (8, 10). 11. Support structure according to one of the preceding claims,
characterized ,
that the support triangle (2, 2 ') is essentially rigid. 12. Support structure according to claim 11,
characterized ,
that the support triangle (2, 2 ') is made of profile material. 13. Support structure according to one of the preceding claims,
characterized ,
that the support triangle (2, 2 ') consists of aluminum or an aluminum alloy. 14. Support structure according to one of the preceding claims,
characterized ,
that at least some of the weld connections are replaced by detachable screw connections.

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