EP0006828A1 - Retaining construction and set of construction elements for its erection - Google Patents

Abstract

1. Retaining structure with construction elements of the same kind, prefabricated and stacked, said elements being provided with branches extending from a center, two of said branches being visible branches (5) and, as it so happens, one of said branches being an anchoring branch (6), all branches of the stacked construction elements being supported one upon the other, wherein said visible branches (5) of the construction elements (3, 3') stacked in neighbouring piles of elements interlock transversely with respect of the piling up direction and wherein the stacked construction elements (3, 3') are secured among themselves by elements (7, 8, 13, 14), respectively (9) interlocking in the piling up direction.

Description

The present invention relates to a support structure with similar, pre-fabricated components stacked on top of one another, which have legs extending from a center point, of which two legs form viewing legs, wherein all legs of stacked components are supported on one another. Such a support structure is described in FR-PS 1 501 277. The components have an essentially star-shaped cross section and they lie on top of one another with their full end faces in the stacked state. The elements do not overlap or interlock and are only secured by mutually interlocking legs. There is only a loose connection between the elements of adjacent stacks of stacked elements. The elements are full profiles of a certain height and they are spaced from each other. They are therefore voluminous, heavy and correspondingly expensive in relation to a certain overall height. The legs lying in the supported soil do not result in particularly effective anchoring in terms of their volume and weight.

It is the aim of the present invention to create a support structure of high stability by means of loosely stackable components at low costs. This aim is achieved according to the invention in that the viewing legs of adjacent stacks of components engage in one another transversely to the stacking direction, and in that the components stacked on top of one another are secured to one another by elements which interlock in the stacking direction are. The interlocking of the viewing legs connects adjacent stacks of components, which increases stability. The components are spaced one above the other and are relatively flat and light. The anchoring legs lying at a distance above one another in the supported soil result in a particularly effective anchoring.

• Fig. 1 zeigt ein erstes Stützbauwerk im Querschnitt,
• Fig. 2 zeigt das erste Stützbauwerk in Draufsicht, in etwas kleinerem Masstab,
• Fig. 3 zeigt eine Vorderansicht des ersten Stützbauwerks,
• Fig. 4 und 5 zeigen erste Bauelemente in Draufsicht,
• Fig. 6 zeigt schematisch eine Draufsicht auf eine Ecke eines Stützbauwerks.
• Fig. 7 und 8 zeigen ein zweites Stützbauwerk in Vorderansicht bzw. in Draufsicht,
• Fig. 9 zeigt einen Schnitt durch eine Ausführungsvariante des zweiten Stützbauwerks und
• Fig. 10 und 11 zeigen wei.tere Ausführungsvarianten in Draufsicht.

The invention will now be explained in more detail with reference to the drawing, which shows exemplary embodiments of the support structure according to the invention:

• 1 shows a first supporting structure in cross section,
• 2 shows the first supporting structure in plan view, on a somewhat smaller scale,
• 3 shows a front view of the first supporting structure,
• 4 and 5 show first components in plan view,
• Fig. 6 shows schematically a top view of a corner of a support structure.
• 7 and 8 show a second support structure in front view and in plan view,
• Fig. 9 shows a section through an embodiment of the second support structure and
• 10 and 11 show further variants in plan view.

The retaining wall shown in FIGS. 1-3 serves to support a fill 1 on the grown terrain indicated by a dash-dotted line 2. The support Wall consists of stacks of flat components coupled together. Each stack mainly consists of star-shaped basic elements 3, each of which has legs extending from a node 4. These are two viewing legs 5 and an anchoring leg 6 lying in the heaped-up material or in the area of excavation of the grown terrain. In the exemplary embodiment shown, the stars are uniform, ie the legs have the same length and each close an angle of 120 ^o between each other.

The basic elements 3 have a cylindrical cam 7 of the same height at the node 4 and at the end of the anchoring leg 6, and a lower cylindrical cam 8 at each end of the viewing leg 5. These cams 7 and 8 are dimensioned such that they can engage in circular, flat recesses 9 on the top of the nodes 4 and the leg ends. For reasons yet to be explained, the cams engage with a little play in the recesses, this play being somewhat larger on the viewing legs than in the nodes and the anchoring legs. Through holes 10 are provided in the area of all the cams 7 and 8 and, according to FIG. 1, can serve to introduce anchoring piles 11. Instead of the anchoring post shown in FIG. 1, a longer post could also be provided, which is threaded at the upper end of the stack, so that the stack can be pretensioned by means of a nut.

At the upper and lower ends, similar support or cover elements 12 are provided, which differ from the basic elements 6 only in that the anchoring leg 6 is missing. They are particularly desirable as the crown of the retaining wall, because under certain circumstances an anchoring leg no longer engages in the fill and is therefore useless and aesthetically undesirable.

As FIGS. 1 and 2 show, the retaining wall can be slightly inclined against the slope. If the retaining wall is also slightly curved according to Fig. 2, different radii of curvature result at different heights, which in turn means that the mutual position of adjacent stacks is not exactly the same, i.e. In the upper part of the wall, the components of adjacent stacks are slightly closer together than at the lower end. This adjustment is possible thanks to the fact that the cams of the viewing legs 5 have some play in the depressions, for example a play of 2 cm.

Fig. 6 shows schematically how a corner can be formed in the support structure. In addition to the basic elements 3 already described, straight elements 13 are provided which have cams 8 and depressions 9 at the ends and can thus be installed between the viewing legs of the basic elements. However, it would also be possible to construct the corner with other elements, for example exclusively with basic elements or with the interposition of floor or corner elements according to FIG. 5.

The set of components shown can not only be used for the production of continuous supporting structures, that is to say in particular retaining walls, but individual stacks of elements spaced apart from one another can be provided completely in the ground as slope protection. Such a slope stabilization can be produced quickly and inexpensively, especially after landslides have taken place, whereupon the slipped material can be transported back. Special drilling or excavation work is hardly necessary because the individual stacks can be secured using anchor piles.

Different versions are possible. So can the angle between the viewing legs 5 can be chosen smaller. For example, T-shaped basic elements could be used to produce a retaining wall with a flat visible surface. If necessary, the anchoring legs 6 could also be made somewhat longer than the viewing legs 5. There could also be elements which, in addition to two viewing legs, have two anchoring legs which enclose an acute angle.

7 and 8 show an embodiment which largely corresponds to that described above. Corresponding parts are designated the same as in the previous figures. The main difference is that the star-shaped components 3 'do not have any protruding cams, but only recesses 9. Instead of the cams 7 and 8, separate cylindrical connecting elements 13 and 14 are provided, which engage in the recesses 9 and thus the components 3 in support the stacks or secure the stacks to each other on the interlocking viewing legs. The connecting elements 13 are higher than the connecting elements 14. All connecting elements have an axial channel through which a pile can be inserted for anchoring in the ground or for additional stabilization of the stack. The ends of the legs 5 and 6 are shaped in such a way that the ends of the stacked viewing legs overlap in a hexagonal manner, as shown in FIG. 8. At certain points, a two-leg component 12 'can be used instead of a component 3', one leg of which is located at the front as a viewing leg, while its second leg is located in the ground as an anchoring leg. This creates a gap 15, which are used, for example, for planting with a larger plant f. ₃ nn. The production is considerably simplified if only quasi-flat elements 3 'and 12' with flat depressions 9 on the one hand and cylindrical connecting elements 13 and 14 on the other have to be produced instead of the elements 3 with un equally long protruding cams. In particular, it becomes much easier to provide sets of cams 13 and 14 of different, coordinated heights, and thus to predetermine the vertical distance between adjacent components 3 'and 12'. In the borderline case, the components 3 'can be installed without spacing, for example for bank structures, in which case connecting elements are to be provided whose height now only corresponds to twice the depth of the depressions 9.

As indicated in dash-dotted lines in FIGS. 7 and 8, upper end elements 16 can be provided, which are similar to elements 12 'as a whole, but only have a recess 9 in the center on one side for receiving a connecting element 14. Loose spacer elements 17 are placed under the ends of the legs of these end elements.

FIG. 9 shows an embodiment variant of a low supporting structure, which is largely constructed from elements 12 '. An element 3 'is only inserted at one point in order to achieve a certain anchoring. However, there could also be no element 3 'with anchoring leg at all, or more such elements could be provided.

Figures 10 and 11 show variants with additional anchoring. 10, elements 12 'are coupled at certain levels to the anchoring legs of the elements 3', which bring about additional anchoring. This additional anchoring can be made even more effective if, according to FIG. 11, elements 3 'are in turn coupled to the anchoring legs of the front elements 3' at certain levels.

The components shown and described are preferably used for the production of supporting structures for inclusion lateral pressures used, but they can also be used to manufacture load-bearing structures such as bases, supports and the like. Of course, buildings can also be created that have both a supporting and laterally supporting function.

Claims (13)

1. Support structure with similar, pre-fabricated components stacked on top of one another, which have legs extending from a center point, of which two legs form viewing legs, wherein all legs of stacked components are supported on one another,
characterized,
that the viewing legs (5) of adjacent stacks of components (3) engage in one another transversely to the stacking direction, and that the stacked components are secured to one another by elements (7, 8, 13, 14) or (9) which interlock in the stacking direction. 2. support structure according to claim 1,
characterized,
that the elements are integrally formed cams (7, 8) or separate connecting elements (13, 14) or depressions (9). 3. Support structure according to claim 2,
characterized,
that the cams (7, 8) or connecting elements (13, 14) are higher than the depressions (9), such that the legs lie one above the other in the stack of components. 4. Support structure according to one of claims 1-3, characterized,
that the components have, in addition to two viewing legs (5), an anchoring leg (6) which lies in the supported material (1). 5. Support structure according to one of claims 1-4,
characterized,
that shorter cams (8) are attached to the viewing legs (5) than to the anchoring legs (6), or shorter connecting elements (14) lie between the viewing legs than between the anchoring legs. 6. Support structure according to one of claims 1-5,
characterized,
that the cams (7, 8) or connecting elements (13, 14) and depressions interlock with one another at least on the viewing legs. 7. supporting structure, in particular according to claim 1,
characterized,
that stacks consisting of a number of stacked components (3) are provided, which are spaced apart. 8. support structure according to claim 7,
characterized,
that stacked in the ground at a distance from each other are provided as slope protection. 9. Support structure according to one of claims 1-8,
characterized,
that components (12) with only two viewing legs are present. 10. Support structure according to one of claims 1-9, characterized,
that the components (3) have through holes (10) into which anchor piles embedded in the ground can engage. II support structure according to one of claims 1-9,
characterized,
that identical components (3, 3 ', 12, 12') are coupled to the anchoring legs (6) of at least some of the components (3, 3 ') in order to improve the anchoring. 12. Set of components for the construction of supporting structures, marked,
through flat, star-shaped or T-shaped basic elements (3), which, starting from a center point, have two viewing legs (5) and at least one anchoring leg (6), the basic elements for receiving cams (7, 8) or connecting elements (13, 14) serve and have depressions (9) for non-displaceable stacking. l3.Satz according to claim 12,
characterized,
that components (3 ', 12') with plane-parallel end faces and shallow recesses (9) are provided with pairs of connecting elements (13, 14) of different heights matched in order to stack the components at different mutual distances.

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