The invention relates to a support structure of a cover of a structure according to the preamble of patent claim 1.
Covers for structures that are capable of being inserted into the ground are known for instance from EP 1031664 A1 or DE 10 2011 051 545 A1. These known objects are so-called manhole covers. Please note, however, that the present invention also applies to support structures of rectangular covers, e.g. to covers of surface drainage channels, i.e. it follows that the covers can also have openings.
Covers of this type are frequently made of cast iron or plastic. To keep material consumption down, the covers are constructed of a surface-forming portion on the one hand, and of support structures to support this area on the other hand. The covers and their supporting structures known from the aforementioned documents are stable, but the material consumption is considerable.
The invention addresses the problem of further developing a support structure of the aforementioned type in such a manner that the same stability can be achieved at a reduced cost and amount of materials.
This problem is solved by a supporting structure according to claim 1 and a process for producing the same according to claim 5.
This problem is solved in particular for a support structure of a cover of a structure capable of being inserted into the ground, e.g. of a shaft or channel, wherein the cover comprises a traversable surface and the support structure extends downwards under said cover into the structure and comprises beam-shaped supports in such a manner that the lower support sides facing away from the surface are subject to a tensile stress when a load is applied to the surface, by substantially symmetrically configuring between two areas a thickness of the supports with minimum tensile stress in an increasing manner up to a maximum value and then, in turn, in a decreasing manner to form a spherical shape in a bottom view of the cover. I.e. the point is not that the support has larger height dimensions, i.e. is larger in the vertical direction, but in its thickness, resulting in a type of spindle shape in a horizontal section. It is of course possible to simultaneously combine this change in thickness with a change in height of the support structure.
The cover is preferably formed as an integral cast part, allowing for a very simple production. In particular, here the design as a spherulitic cast iron part, resulting in high stability, is preferred.
The thickness of the side surfaces of the support facing each other, which define the support, are preferably formed divergent towards the surface (i.e., in the installed state from the bottom upwards) for the formation of draft angles. The angle of inclination of these surfaces in this case remains constant over the entire length of the support; thus remains unchanged in the thinner regions of the support as compared to the thicker areas of the support. In this way, an optimum demolding of the forming model from the molding material (molding sand) is ensured.
Such a support structure can be dimensioned based on the following steps:
Below, two exemplary embodiments of the invention are explained in detail. In the figures:
In the following description, the same reference numerals are used for identical and identically acting parts.
The relatively lowest tension acts on the supports 22 in the areas A, A′, which are adjacent to the “coupling areas” at the ends of the supports 22. In a central area M between the areas A, A′, the supports 21 now have a greater thickness D than in the areas A, A′, adjacent to the ends of the supports 22. The side surfaces 25, 26 of the supports 21 (and also of the supports 22) have a uniform inclination angle relative to the vertical plane (or the plane perpendicular to the surface 11). Furthermore, corresponding radii are obviously provided in the transition areas to the plane forming the surface 11.
The same design principle is also used in the channel cover of
For dimensioning the supporting structure 20, first the required thickness D of the supports 21 for a specified load of the cover 10 (largely perpendicular to the surface 11) is determined with the proviso that the support 21 has a constant thickness D. Then the load present in the areas A, A′, i.e. in the area of the transitions to the radial supports 22 is determined, from which in turn the necessary thickness of a support (of constant thickness) is derived. Finally, a transition between the two thicknesses that is as uniform and crack-free as possible is derived. This results in material savings in the areas which do not have to have maximum thickness, a procedure that results in surprisingly substantial material savings.
Number | Date | Country | Kind |
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10 2014 104 744.3 | Apr 2014 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/057324 | 4/2/2015 | WO | 00 |