DE3920514A1 - Concrete prefabricated slope block - has coarse-mesh plastics anchoring grille grouted into rear wall - Google Patents

Abstract

The prefabricated slope block is for a supporting structure built up by placing the concrete blocks one above the other. In plan view, the block is a hollow body with a closed peripheral wall, open to the top and at least partly to the bottom, with parallel horizontal edges. At the rear wall of the block (20), the ring (10) of reinforcing members is joined to a coarse-mesh anchoring grille (12), which is grouted into the rear wall and protrudes from it in the rearwards direction. The grille is in one piece and of high-tensile plastic resistant to bending loads. ADVANTAGE - Simple anchoring, with no backfilling or compacting problemsn.

Description

The invention relates to a prefabricated concrete slab for the construction Support structures that can be planted with greenery, which are placed on top of a slope the gap is formed between two slope stones lying at a distance below it, the slope stone consisting of a substantially square in plan view, all around closed, open at the top and at least partially below hollow body exists, the horizontal edges of which run parallel to each other, and with a along the front wall there is a full width adjoining floor bridge.

A slope stone of this type is known from EP-A 2 12 357 and is used for Manufacture of greenable supporting structures using geotextiles laid the rear wall of the slope stone and behind it for anchoring in compacted soil can be embedded.

In practice it has been shown that the use of the known geotextiles can cause considerable difficulties in compacting the soil because the Textiles are very compliant and soft and can also be easily damaged, when soil is mechanically introduced and compacted for backfilling. One of the big difficulties is e.g. B. that the textile webs in machine Introducing the backfill through the inevitable uneven filling on the one hand and the sinking of the heavy vehicles on the other hand no longer in the desired even stratification in the soil, are wavy and in the worst case are confused with each other or slide into each other, which leads to a reduction in the anchoring depth can. An attempt has already been made to shorten the anchoring depth in this way thereby to avoid that the slope ends of the textile web with in Anchored in construction nails or iron bars. These Measure is unsatisfactory, since such rods are mechanical Disrupt the introduction of the backfill and on the other hand because of the low Tear out the interweaving of the geotextile weave structure on the fastening.  

Another disadvantage of textiles is that they are proportionate tightly woven textiles when backfilling so-called rolly and cohesive Material, d. H. a high-quality fine-grained material. Therefore can upcoming material, d. H. coarser and sharp-edged soil, not used be, so that additional transport costs arise. Since the geotextiles in Sheets must be cut approximately the width of the slope stones Need to weld the edges of these sheets so that the loose Tissue does not open from the edge. A large-area and one-piece installation such textiles on the slope, which further increases the stability of the soil could hardly be increased. This also closes the fact with that geotextiles an additional soil improvement with alkaline Do not allow supplements because they are not stable in an alkaline environment. Out for this reason there is always an additional coating on the contact surfaces Concrete geotextile necessary.

The invention has for its object to a prefabricated hillside Building support structures to create the slope in a simple manner is anchoring, the anchoring being easy to the static local conditions is customizable and not difficult if the backfill and Compression should be done mechanically.

This object is invented for a prefabricated concrete slab solved in that in the circumferential wall of the as a hollow body trained Hangstein arranged reinforcement in the area of the rear wall with connected to a fastening section of a large-mesh anchoring grid is that the anchoring grid is concreted into the back wall and out of the Rear wall emerges to the rear and that the anchoring grid from one rigid and high tensile plastic material.

The measures of the invention advantageously achieve that is possible to a slope stone with a concrete anchored connection create the local conditions and the static requirements appropriately dimensioned anchoring grid connected as an extension can be, with the extension lying flat on the ground also with heavy construction machinery is passable when backfilling and because of the coarse meshing results in very good interlocking even with coarse soil. Thereby  there is the advantage that even cohesive and sharp-edged soil is processed can be. Due to the better interlocking due to the coarse mesh, the Stability of the soil significantly improved.

According to a further embodiment it is provided that the plastic material of the Anchoring grid is alkaline resistant, which has the advantage that the Soil can also be improved by adding lime or cement.

Depending on the type of processed and used for backfilling Soil is provided that the mesh of the anchoring grid elongated Enclose rectangular areas with an aspect ratio of approximately 1: 6 to 1:10. This mesh size ensures that even coarse soil for Backfilling can be used, d. H. even if there is no rolling material Is available is a material exchange as in the known textile webs not mandatory.

In the interest of the most versatile adaptability to the local Circumstances and the static requirements provide that the Ver anchor grid from the rear wall of the hollow body in the area of the bottom Edge with a length of at least 1.5 times an elongated Rectangular surface emerges. This measure results in one Simplification in the manufacture and storage of the slope stones and on the other hand the Prerequisite for any extension following the anchoring can be designed, d. H. the extension can take into account the circumstances speaking can be of any length and also in terms of tensile strength and Elongation to be adapted to the local conditions. This does not decrease only the storage costs considerably, but also the material costs for the Anchorage grid to be connected to Hangstein if the requirements regarding Tensile strength and elongation are lower and a correspondingly lighter off leadership can be used.

For easy attachment of the extension of the anchoring grid to the in the Concrete block anchored grating, the invention provides that the free End of the anchoring grid is bent to extend that semicircular an extension piece from the anchoring grid with a half as well circularly bent section is provided and with the elongated Lattice bars through the rectangular surfaces of the semicircularly curved free End is inserted, and that to connect the extension piece with the  free end of the anchoring grid a rod between the nested, bent sections is pushed.

This type of connection of the extension piece with the slope stone side Anchoring grid is extremely easy to manufacture, very safe and can on the construction site without additional aids.

According to a further embodiment of the invention it is also provided that the Extension piece of the anchoring grid across the width of a variety extends from slope stones. This is a very large-scale anchoring in the Slope possible, which can improve the stability of the slope. This is particularly advantageous when adding alkaline Aggregates an additional soil improvement to increase the stand security of the ground is sought.

Of course, such anchoring grids can also be designed differently Concrete elements for supporting structures can be concreted in the same way.

The invention with its advantages and features also results from the following description of an embodiment in connection with the Claims and the drawing. It shows

Figure 1 is a reinforcement grid for a hillside with an anchoring grid attached.

Figure 2 is a section through a stone with a cast-in slope and provided with an extension piece anchorage grid.

Fig. 3 shows a section through a supported steep slope using slope stones and anchoring grids according to the invention.

In Fig. 1, a reinforcement cage 10 for a hillside is shown, to which an anchoring grid 12 is fastened with binding wire 13 . The anchoring grid 12 is bent through half of its length by 90 ° and protrudes from the reinforcement ring 10 .

The anchoring grid consists of a one-piece, as well as rigid and high tensile plastic material with mesh, the elongated rectangular surfaces with an aspect ratio of about 1: 6 to 1:10 and preferably about 1: 8 enclose. The longitudinal extension of the rectangular surfaces runs in the direction of the Mooring cable. This is in the interest of the least possible stretch Anchoring grid stretched in the direction of the anchoring cable, so that thinner Bars in the longitudinal direction of the rectangular area and thicker bars in the transverse direction of the Rectangular area arise. This stretching not only increases stability, but also the flexibility of the longitudinal webs, so that even coarse for backfilling Soil can be used as this works very well with the anchoring grid interlocked. This means that the coarse and cohesive material that is usually present Soil can be used for backfilling, so that transport costs are eliminated Previously when using geotextiles to remove the rough Soil and the transport of rolling soil were inevitable.

In Fig. 2 a slope stone with a concrete anchoring grid is shown in section. The anchoring grid can be connected to the reinforcement grid or can be concreted in independently of it. The anchoring grid consists of a path comprising three rows of rectangular surfaces, a path section of approximately 1.5 rectangular surfaces being concreted into the rear wall of the slope stone 20 . The anchoring grid 12 emerging from the rear wall of the slope in the region of the rear edge on the floor side has a length of at least 1.5 times an elongated rectangular surface 14 and is bent in a semicircular or sinusoidal manner in the region of the free end 22 . Extension pieces 24 made of the same material, preferably with the same lattice structure, are used to lengthen the concreted-in anchoring lattice, which length and width can be dimensioned differently in accordance with the required statics and the local conditions. It is also seen before that extension pieces from an anchoring grid with a lower tensile strength are used if the local conditions allow.

To attach the extension piece 24 , this is also bent up at the end 26 on the hillside side in a semicircular or sinusoidal manner and is inserted with the elongated lattice webs in the region of the curvature through the rectangular surfaces of the bent up free end 22 of the anchoring lattice 12 embedded in concrete. The two nested semi-circular sections result in a free space, as can be seen in FIG. 2, in which a rod 28 can be inserted to connect the two end sections. This rod 28 can consist of a galvanized reinforcing steel or another, non-coring and highly flexural material.

Since the anchoring grid is made of an alkaline-resistant plastic material is made, it is resistant to lime or cement, which Possibility of an additional floor improvement or an increase in the stand safety of the soil by adding such aggregates.

The invention also offers the possibility of adapting the anchoring to the ground and slope conditions by a different design of the Ver extension piece 24 , which can be attached either in a smaller width than the slope stones or in a larger width to the concrete embedded in the slope stone Ver anchor grid . In particular, it is provided that the extension piece of the anchoring grid extends across the width of a large number of slope stones and is suspended in several adjacent slope stones. This means that the stability of the soil can be increased considerably, even if the quality of the soil is not particularly good.

In Fig. 3 is built from prefabricated slope stones, greenable support wall is shown, in which the individual slope stones 20 are provided with a toned anchor grid 12 , the free ends 22 are connected to the slope end of the extension piece 24 via a rod 28 . The extensions can be of different lengths. If the local conditions with regard to the stability of the soil allow this, it is also provided that an extension piece is not attached to the free ends of the anchoring grid embedded in concrete in all stone layers.

The anchoring grids are known per se and are commercially available by the meter produced. They consist of a polymer material, e.g. B. selected poly olefins that are chemically inactive. Therefore, they are also for long-term reinforcement suitable.

Claims (6)

1. Prefabricated concrete slab for the construction of supporting structures, which are formed by placing slabs on top of each other, the slab consisting of a hollow body which is essentially all-round closed in plan view, open at the top and at least partially below, the horizontal edges of which run parallel to one another, thereby featured,

• - That a in the circumferential wall of the hillside ( 20 ) arranged reinforcement ring ( 10 ) in the region of the rear wall with a fastening section of a large-meshed anchoring grid ( 12 ) is connected,
• - that the anchoring grid is concreted into the rear wall of the concrete block and emerges from the rear wall to the rear,
• - And that the anchoring grid consists of a one-piece, bending-resistant and high tensile plastic material.

2. slope stone according to claim 1, characterized in

• - That the plastic material of the anchoring grid is alkaline resistant.

3. slope stone according to claim 1 or 2, characterized in

• - That the mesh of the anchoring grid ( 12 ) enclose elongated rectangular surfaces with an edge ratio of about 1: 6 to 1:10.

4. slope stone according to one of claims 1 to 3, characterized in

• - That the anchoring grid ( 12 ) emerges from the rear wall of the slope stone ( 20 ) in the region of the bottom edge with a length of at least 1.5 times the elongated rectangular area.

5. slope stone according to one or more of claims 1 to 4, characterized in

• - That the free end ( 22 ) of the anchoring grid ( 12 ) is bent semicircular or sinusoidal for extension,
• - That an extension piece ( 24 ) from the anchoring grid with a likewise semicircular or sinusoidally bent section ( 26 ) see ver and is inserted with the elongated grid bars through the rectangular surfaces of the semicircularly bent free end ( 22 ),
• - And that for connecting the extension piece ( 24 ) with the free end ( 22 ) of the anchoring grid ( 12 ) a rod ( 28 ) is pushed between the nested, bent sections.

6. slope stone according to one or more of claims 1 to 5, characterized in

• - That the extension piece ( 24 ) of the anchoring grid extends across the width of a plurality of slope stones.