DE20106495U1 - Plate for distributing loads or covering pits or transitions - Google Patents

Description

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Description:

Plate for distributing loads or for covering pits or crossings

The present invention relates to a plate for distributing loads over a larger area, in particular for crane feet, or for covering pits or crossings, in particular for walking or driving over, with a plate underside which rests on the ground during use, and with a plate upper side which forms the load-bearing or walkable or driving over surface.

In order to support and distribute a point-shaped or small-area load, such as the base of a mobile or stationary crane, over a larger area, wooden planks or beams laid criss-cross on top of each other are still commonly used in practice. These have the advantage that they are relatively light individually and can be lifted and moved by one person, and that they are relatively inexpensive. The disadvantage, however, is that these wooden planks or beams have a limited load-bearing capacity. In addition, if wooden beams or planks are laid loosely on top of each other, there is a risk that they will shift when loaded, which can lead to dangerous situations because the load can no longer be supported. To form temporary covers or walkways, e.g. on excavation pits or trenches, solid steel plates have been used up to now, which, due to their

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relatively large thickness, which is necessary to achieve the necessary load-bearing capacity, are very heavy. This results in an unfavourable ratio of weight to load-bearing capacity, which disadvantageously leads to high material costs and a correspondingly high weight to be transported and moved on the construction site, for example.

Furthermore, support plates are known to be used in individual cases, which are made of double-T profiles arranged parallel to one another and welded together at their abutting edges. With these support plates, it is no longer possible for individual parts to shift against one another, as is the case with wooden beams or planks, but these known support plates are very heavy on the one hand and are not symmetrical in their load-bearing behavior on the other. This asymmetry is due to the fact that the support plates are made up of parallel profiles, whereby this arrangement is much more stable in the longitudinal direction of the profile than across it. The use of these support plates therefore requires a great deal of thought, for example from a crane operator or crane assistant, who must ensure that the longitudinal direction of the profiles forming the support plate is correct in accordance with the load occurring and the ground conditions found. Experience in practice has shown that the necessary care is not always guaranteed.

The object of the present invention is therefore to create a plate of the above-mentioned type which avoids the disadvantages described and which has a high load-bearing capacity with a relatively low weight, whereby the load-bearing capacity of the plate should be independent of its orientation. In addition, the plate should be durable and stable and thus safe to use.

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This object is achieved according to the invention with a plate of the type mentioned at the outset, which is characterized in that it is formed from a lower and an upper cover plate with connecting webs arranged therebetween.

The panel according to the invention is, on the one hand, relatively light in weight because it is largely a hollow body. At the same time, however, it is particularly stable because the combination of cover panels and connecting webs arranged between them forms a highly resilient spatial structure that can absorb high small-area or point loads on one side and distribute them over a larger area on the other side. This panel is also very stable and resilient when used as a cover or bridge, even if it is only supported on a supporting surface with two end areas of its underside.

In a further embodiment of the plate, it is preferably provided that the cover plates are arranged parallel to one another. This results in a simple construction of the plate because all connecting webs can be designed with the same height, so that no different heights of connecting webs are required.

Alternatively, the cover plates can be spaced apart from one another at different distances across the surface of the plate, with the distance between the cover plates preferably decreasing in at least two opposing directions starting from the center of the plate. This increases the manufacturing effort, but at the same time the ratio of load-bearing capacity to weight of the plate is further improved.

Furthermore, the connecting webs are preferably formed by material strips whose surface planes run perpendicular to the surface plane of the lower cover plate. This gives the plate particularly good stability against loads in the direction perpendicular to its surface plane.

In order for the plate to be able to absorb high shear forces acting in different directions, the connecting webs preferably run crossing each other in at least two different directions.

Preferably, the two different directions of the intersecting connecting webs form an angle of 90° with each other, so that the connecting webs form a rectangular honeycomb arrangement when viewed from above. This achieves a very high level of symmetry in the load-bearing capacity of the panel.

In order to achieve a stable cohesion of the connecting webs and to make their pre-assembly as simple as possible, it is preferably provided that they are slit and inserted into one another at their intersection points, on the one hand from their upper edge and on the other hand from their lower edge, over half their height.

The invention further proposes that the connecting webs are designed with projections arranged at intervals on their lower edge and/or on their upper edge, the height of which corresponds to the thickness of the lower and/or upper cover plate minus a welding preparation depth, and that openings are made in the lower and/or upper cover plate to accommodate these projections. This design ensures that, simply due to the shape of the connecting webs and the cover plates, they are held together mechanically by their mutual engagement.

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Preferably, the further connection of the parts of the plate with each other also takes place in the area of these mechanical interventions.

In order to make the mechanical connection of the parts of the plate as effective as possible and to weaken the cover plates as little as possible through the openings provided in them, the projections are conveniently arranged at the intersection points of the connecting webs. Accordingly, the openings in the cover plates are also located at the intersection points of the connecting webs, resulting in a cross-shaped outline of the openings in the cover plates.

For reasons of stability and cost, the cover plates are preferably cut from sheet steel plates and the connecting webs are cut from sheet steel strips, with the cover plates and the connecting webs being welded together in the openings. The welding work can be carried out easily and without hindrance from the upper and lower outside of the plate. This also makes it possible to automate this welding work easily and without any problems, so that the plate can be manufactured inexpensively with little personnel expenditure and with high-quality welds. The use of aluminum as a material is also conceivable to create a lightweight plate that can still be handled manually.

For manufacturing reasons in particular, the plate preferably has a rectangular or square outline when viewed from above. The surface area of the plate, the height of the connecting webs and the material thicknesses of the cover plates and connecting webs depend on the loads to be absorbed and the resulting requirements.

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In order to be able to store several panels, of which four are required for a crane, in a space-saving manner when not in use, the panel according to the invention is advantageously provided with an upwardly protruding stacking corner at each of its four corners or at two diagonally opposite corners. These stacking corners ensure that two panels placed on top of one another can no longer move against one another and thus assume a secure position relative to one another. Due to their size and weight, which are usually required in practice, the panels according to the invention can generally no longer be handled manually. To facilitate handling by crane, the panel is advantageously provided with at least two crane eyes on its side edges or corners.

Preferably, it is further provided that one of the stacking corners and the crane eyes are designed as a single component, wherein the stacking corner in each case has an opening in its corner area forming the eyelet.

An embodiment of the invention is explained below. The figures of the drawing show:

Figure 1 shows a plate during its production in an exploded view of its individual parts, in a perspective partial view, and

Figure 2 shows a section of a finished plate in plan view.

The embodiment of a plate 1 shown in Figure 1 of the drawing comprises a lower cover plate 2, an upper cover plate 3 and several connecting webs 4, 4' arranged between them. For reasons of clarity, only one connecting web 4 of a

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first running direction and a connecting web 4' of a second running direction running perpendicular to it
The running directions of the connecting webs
4, 4' are indicated by dotted lines on the
both cover plates 2, 3 and form a regular square grid parallel to the cover plate edges.

The connecting webs 4 are extending from their upper edge 42
provided with slots 40 which extend over half the height of the connecting webs 4. In the opposite arrangement, the connecting webs 4' are provided with slots
40', which also extend from the lower edge 41' over half the height of the connecting bridges
4'. In this way, the connecting webs 4, 4' can be inserted into one another at their crossing points 45, so that the lower edges 41, 41' and the
Upper edges 42, 42' of the connecting webs 4, 4' a uniform
Take up altitude.

Immediately next to the slots 40, 40' and
Exactly opposite these are projections 44, 44' on the lower edges 41, 41' and the upper edges 42, 42' of the
Connecting bars 4, 4' are provided.

The cover plates 2, 3 are flat plates that are
the intersection points 45 of the connecting bridges 4, 4' with
cross-shaped openings 24, 34. These openings 24, 34 are shaped and dimensioned so that
that they exactly accommodate the intersecting projections 44, 44' of the connecting webs 4, 4'. The height of the projections 44, 44' is equal to the thickness of the cover plates 2,
3 minus a welding preparation depth. When the cover plates 2, 3 are assembled with the
The projections 44, 4' are located between the connecting webs 4, 4'.
44' on one side slightly above the underside 21 of the lower cover plate 2 and on the other

Side slightly below the upper side 32 of the upper cover plate 3. In the areas of the openings 24, 34 with the projections 44, 44' located therein, the final connection of the cover plates 2, 3 with the connecting webs 4, 4' takes place here.

The two cover plates 2, 3 are expediently cut from steel plates and the connecting webs 4, 4' are expediently cut from steel sheet strips, whereby the thickness and the other dimensions of the parts of the plate 1 are based on the load to be absorbed in accordance with the respective intended use. The connection of the cover plates 2, 3 to the connecting webs 4, 4' is expediently carried out here by welding, whereby preferably a cross-shaped weld seam is applied in the area of the openings 24, 34 and the projections 44, 44' located therein. After welding, the projections 44, 44' are flush with the underside 21 of the lower cover plate 2 and the top side 32 of the upper cover plate 3.

As Figure 1 clearly shows, the plate 1 is easy to manufacture because the individual parts, namely the cover plates 2, 3 and the connecting webs A, 4', first simply have to be put together after they have been cut to size, e.g. using a laser cutting device. Welding then takes place on the easily accessible underside 21 of the lower cover plate 2 and on the equally easily accessible top side 3 2 of the upper cover plate 3. Welding in the area of the top side 22 of the lower cover plate 2 or the underside 31 of the upper cover plate 3 or between the connecting webs 4, 4' inside the plate 1 is not necessary.

It is also clear that the connecting webs 4,4' are identical parts, with only the alignment of the connecting webs 4, 4' in one running direction being different.

is reversed as in the other direction.

Figure 2 of the drawing shows a top view of a corner area of a finished plate 1, with the view falling on the top side 3 2 of the upper cover plate 3. The lower cover plate 2 is invisible in the background.

A corner 10 of the plate 1 is shown at the top left in Figure 2. A stacking corner 5 is welded to this corner 10, which also consists of a sheet steel molded part. At least one further stacking corner 5 is attached to the diagonally opposite corner of the plate 1, which is not visible in Figure 2, in order to enable several plates 1 to be stacked on top of one another in a way that prevents them from shifting. A stacking corner 5 is advantageously attached to all four corners of the plate 1.

Furthermore, an opening 5' is provided in the stacking corner 5 exactly in the corner area, which forms a crane eye. This makes it easy to handle the panel 1 using a crane.

The openings 34 in the upper cover plate 3, in which the projections 44, 44' of the connecting webs 4, 4' are located, are located at the intersection points 45 of the connecting webs 4, 4' running under the upper cover plate 3, which are shown here in dashed lines. In these areas, the connecting webs 4, 4' and the upper cover plate 3 are welded together. The connection between the lower cover plate 2 and the connecting webs 4, 4', which is not visible here, is designed in the same way.

Claims (14)

1. Plate ( 1 ) for distributing loads over a larger area, in particular for crane feet, or for covering pits or crossings, in particular for walking or driving over, with a plate underside ( 21 ) which rests on the ground during use, and with a plate upper side ( 32 ) which forms the load-bearing or walkable or driveable surface, characterized in that the plate ( 1 ) is formed from a lower and an upper cover plate ( 2 , 3 ) with connecting webs ( 4 , 4 ') arranged between them. 2. Plate according to claim 1, characterized in that the cover plates ( 2 , 3 ) are arranged parallel to one another. 3. Plate according to claim 1, characterized in that the cover plates ( 2 , 3 ) have different distances from one another as seen over the surface of the plate ( 1 ), wherein the cover plate distance preferably becomes smaller in at least two opposite directions starting from the center of the plate ( 1 ). 4. Plate according to one of the preceding claims, characterized in that the connecting webs ( 4 , 4 ') are formed by strips of material whose surface planes run perpendicular to the surface plane of the lower cover plate ( 2 ). 5. Plate according to one of the preceding claims, characterized in that the connecting webs ( 4 , 4 ') cross each other and extend in at least two different directions. 6. Plate according to claim 5, characterized in that the two different directions of the mutually crossing connecting webs ( 4 , 4 ') form an angle of 90° with one another, so that the connecting webs ( 4 , 4 ') form a rectangular honeycomb arrangement when viewed in plan. 7. Plate according to claim 5 or 6, characterized in that the connecting webs ( 4 , 4 ') are each slotted over half their height and inserted into one another at their crossing points ( 45 ), on the one hand from their upper edge ( 42 ) and on the other hand from their lower edge ( 41 '). 8. Plate according to one of the preceding claims, characterized in that the connecting webs ( 4 , 4 ') are designed on their lower edge ( 41 , 41 ') and/or on their upper edge ( 42 , 42 ') with projections ( 44 , 44 ') arranged at intervals, the height of which corresponds to the thickness of the lower and/or the upper cover plate ( 2 , 3 ) less a welding preparation depth, and that openings ( 24 , 34 ) receiving these projections ( 44 , 44 ') are provided in the lower and/or the upper cover plate ( 2 , 3 ). 9. Plate according to claim 8, characterized in that the projections ( 44 , 44 ') are arranged at crossing points ( 45 ) of the connecting webs ( 4 , 4 '). 10. Plate according to claim 8 or 9, characterized in that the cover plates ( 2 , 3 ) are cut outs from sheet steel plates and the connecting webs ( 4 , 4 ') are cut outs from sheet steel strips and that the cover plates ( 2 , 3 ) and the connecting webs ( 4 , 4 ') are welded together in the openings ( 24 , 34 ). 11. Plate according to one of the preceding claims, characterized in that it has a rectangular or square outline when viewed in plan. 12. Plate according to claim 11, characterized in that an upwardly projecting stacking corner ( 5 ) is attached to each of its four corners ( 10 ) or to two mutually opposite corners ( 10 ). 13. Plate according to one of the preceding claims, characterized in that it is provided with at least two crane eyes ( 5 ') on its side edges ( 11 ) or corners ( 10 ). 14. Plate according to claim 12 and 13, characterized in that one of the stacking corners ( 5 ) and the crane eyelets ( 5 ') are designed as a single component, wherein the stacking corner ( 5 ) in each case has an opening in its corner region forming the eyelet ( 5 ').