DE10055327C1 - Grid plate for construction of 3-dimensional structure has struts within peripheral frame provided within variable spacing or cross-sectional geometry for increasing loading capacity at center of grid plate - Google Patents

Abstract

The grid plate (1) has a peripheral frame (4) with a number of corners (2) joined together by side edges (3), with struts (5) within the frame extending between the corners. The spacing between 2 adjacent struts decreases moving away from one corner, before increasing again moving towards the next corner, or alternatively the struts exhibit an increasing longitudinal loading capacity moving away from the first corner and a decreasing loading capacity moving towards the next corner, provided by varying their cross-sectional geometry.

Description

The invention relates to a grid plate according to the preamble of Claim 1.

Such grating plates are known from DE 39 03 265 A1, around three-dimensional structures in the form of foldable transport bodies be created. Such baskets are only small me exposed to mechanical stress and must in the first place can absorb the internal pressure caused by the cargo acts on the floor and the grid plates.

The invention is based, generic task To improve grid plates so that they have a three dimensional structure with high compressive strength compared allow external pressure.

This task is accomplished by a grid plate with the features of claim 1 solved.

In other words, the invention proposes the pressure load availability along an edge of the frame from the two corners towards a central area of this edge, d. H. to reinforce.

This reinforcement can be due to closer spacing Striving to be realized or through more stable striving. stable In turn, struts can be made with greater material thickness be realized, i.e. by the cross-sectional dimensions with basically the same shape, or by a pressure more stable cross-sectional geometry.  

The invention is based on the consideration that such Lattice panels as upright end walls of a cas ten-like three-dimensional structure can be used or as support additionally arranged inside in such a structure plates. The pressure load is therefore from the outside and the Compressive forces are generated within by the grating plate itself defined level.

The invention is also based on the consideration that the lowest pressure stability of the edges is to be expected there is where they are the greatest distance from one of their two corners exhibit. There is a support effect at the corners themselves through the further edge of the frame adjoining the corner mens, so that here too a sufficiently good Druckbe resilience is given if the distance between neighboring Struts is comparatively large or the strut cross sections are less pressure-resistant, for example by a ring increased material thickness or by a pressure load equally unfavorable cross-sectional geometry.

Due to the arrangement of the struts according to the invention greatest possible pressure resistance of an edge even in the ab stood from the corners of the grid plate. Doing so at the same time realized the greatest possible material savings, by ver the pressure resistance of the edge towards the corners is wrestled.

On the one hand, this means a due to the material savings inexpensive manufacturing option, on the other hand for An application, assembly and laying an easier to handle lower weight, and finally depending on the application purpose of the structures op temporal properties of these structures. With the help of Lattice panels, for example, closed box-like on all sides Structures are formed that serve to absorb liquid, for example as a buffer storage for drainage purposes in the ground,  the high compressive strength results in a problem-free traversability of the floor surface heavy vehicles and on the other hand the largest possible free Internal volume of the drainage tank arranged in the ground for Maximum water intake.

It can advantageously be provided in addition to parallel to the edge extending struts also diagonally extending struts use. With changing distances of the edges parallel running struts to each other can be done through the Diago nal struts a polygonal, almost curved course of this Diagonal struts and thus a lateral derivative of the vertical acting pressure forces take place, so that a particularly before partial, large-scale load distribution and thus a special one high pressure stability is achieved.

In addition to the optimized design of the struts on the Edges of the frame can save even more material Grid plate are provided in the middle of the surface by that less material of the grid plate is provided there for example there are no or fewer struts provided or struts with a smaller cross-section. Especially if due to the aforementioned polygonal or arcuate Force transfer of the middle surface area of the grid plate from Pressure loads are essentially free, can be a significant increase here Liche material savings and thus a correspondingly large Creation of free volume.

Embodiments of the invention are based on the drawing nations explained in more detail. It shows

Fig. 1 is a grid plate according to the invention in perspec TiVi view;

Fig. 2 is a corresponding grid plate for making a three-dimensional structure, as example, a Drainagebox,

Fig. 3 plates the junction between several grids and

Fig. 4 in a perspective schematic view of a three-dimensional structure, for example as a drainage tank.

In Fig. 1, 1 generally denotes a grid plate which is designed almost square and has four corners 2 , edges 3 running between the corners 2 , which together form a square, almost square frame 4 . Struts 5 run within the frame 4 .

Some of these struts 5 run parallel to the edges 3 and are characterized as struts 5 a parallel to the edges. Through the intersecting edge-parallel struts 5 a cells ge forms, through which extend obliquely extending struts, which are identified as diagonal struts 5 b.

Where the edge-parallel struts 5 a cross, holes 6 are provided to avoid material clusters, which also advantageously distribute pressure forces which act in the direction of the plate plane.

On the outside of the frame 4 , pins 7 are provided, which are used for connection to further grid plates. The pegs have a base with an approximately circular cross section and a free end 9 , which is removed from the base 8 and on which a claw 10 is provided in each case. In order to allow elasticity and deformability of the pin 7 , a groove 11 is provided in the base 8 .

By way of example, the grid plate 1 has four cells, which are not crossed by diagonal struts 5 b, but which are filled in by plates 12 . These plates 12 are used for simple removal of the grid plate 1 from a mold with the aid of, for example, suction lifters and can continue to be used for attaching labels.

In FIG. 2, a corresponding, connectable to the grid plate 1 of Fig. 1 grid plate 1 is shown, also with four plates 12. This grid plate 1 of FIG. 2 also has Boh stanchions 6 to avoid material accumulations and also larger bores in the form of sleeves 14 , which have an inner circumferential collar 15 approximately half way up the sleeves 14 for cooperation with the pins 7 , as shown in FIG is shown Fig. 3:
A lower grid plate 1 u is placed in the area of its frame 4 u. A similar grid plate is shown above and de ren reference numerals are each marked with o, so there is a frame 40 of a grid plate 1 o can be seen, with a pin 70 from this upper grid plate 1 o in a sleeve 15 m of a central grid plate 1 m ( Reference number with m ) he stretches. The collar 15 m of the sleeve 14 m can be gripped by both pins 7 o and 7 u of the upper and lower grid plates 1 o and 1 u, so that in this way a simple, arbitrarily expandable attachment of several grid plates is made possible and thus light creating very large structures.

In FIG. 4, a drainage tank can be seen how it can be provided for example as a water reservoir in the ground. The grid plates of FIG. 2 are as longitudinal plates 1 b be characterized and the grating plates according to Fig. 1 as the transverse plates 1 a, said transverse plates 1 a, both the two end plates of the drainage tank form as well as within the drainage tank as an additional supporting plates for increasing the pressure stability of the drainage tank are provided.

As can be seen in particular from Fig. 2, the Längenplat th 1 b have a plurality of sleeves 14 , so that a plurality of cross plates 1 a can be arranged within such a drainage box, depending on the desired compressive strength.

Compressive forces that act on the drainage box from above thus act in the plane in which the cross plates 1 a are set up. They are introduced via the upper edge 3 of the frame 4 of a Querplat th 1 a in the struts 5 of the cross plate.

It is clear from FIG. 1 that the distances between adjacent struts 5 a parallel to the edges initially increase from a corner 2 of an edge towards the center of the edge and then decrease again towards the next corner 2 . In this way, a support effect is taken into account, which results anyway in the area of the corner by the respectively adjacent edge 3 of the frame 4 . Due to the larger distances in the corner areas between adjacent struts 5 , material can consequently be saved and a correspondingly larger holding volume of the drainage tank for water can be made possible.

Since the distances between the struts 5 a parallel to each other on two adjacent edges 3 are each smaller from the corner, the diagonal struts 5 b are based on the different and not always square cell sizes starting from the center of an edge 3 and the force is curved outward curve to the edge 3 adjacent to the right or left of edge 3 . The edge-parallel struts 5 a, on the other hand, guide the pressure forces downwards. At the intersection of the various struts there is a further distribution and branching of the pressure forces, so that overall a very stable and highly resilient Ausgestal device of the cross plates 1 a and thus the entire drainage tanks results.

Claims (3)

1. grid plate for producing a three-dimensional structure, such as a box,
wherein the grid plate has a surrounding frame,
with multiple corners,
and with edges running between two adjacent corners,
and where struts run from one edge to another edge within the frame,
characterized by
that the distances between two adjacent struts ( 5 ) along an edge ( 3 ) starting from a first corner ( 2 ) initially become smaller and larger again towards the second corner ( 2 ),
or that the struts ( 5 ) along an edge ( 3 ) starting from a first corner ( 2 ) initially have an increasingly higher compressive strength in their longitudinal direction due to a more stable cross-sectional geometry or a greater material thickness,
the compressive strength of the struts ( 5 ) towards the second corner ( 2 ) decreases again. 2. Grid plate according to claim 1, characterized in
that struts ( 5 a) running parallel to the edges ( 3 ) are provided,
and an angle (5 b), each of which extend diagonally through a of intersecting edges parallel struts (5 a) cell formed to the edges (3) extending struts. 3. Lattice panel according to claim 1 or 2, characterized in that towards the center of the surface of the lattice plate ( 1 , 1 a) the pressure resilience in the longitudinal direction of the struts ( 5 ) by a smaller number of struts ( 5 ) per surface or by a strut cross-section is formed with a lower material thickness.