DE19848846A1 - Foundation structure for constructions on soft ground has pillars at regular intervals through into the lower hard ground layer with pillar head caps covered by a geo-plastics reinforcement to take the loose ballast - Google Patents

Abstract

The foundation structure, for ground (1) which has a poor load-bearing quality, has pillars (3) at regular intervals extending down into the ground level (2) which can support loads. The heads of the pillars (3) extend over the level of the soft ground (1), to be covered by a reinforcement (5) of geo-plastics to support the layer of loose ballast (6). The pillar heads are formed by curved caps (4), which project over the cross section of the pillars (3) on all sides, with a constant reduction in thickness from the center to the edge.

Description

The invention relates to a foundation structure on low load-bearing according to the subsoil, for the transmission of loads in the deep, load-bearing building ground are arranged at regular intervals, with their heads towering over and over the low load-bearing building ground The heads of the columns are laid with geosynthetic reinforcement, which is connected to a Landfill is charged.

Foundation structures of this type are known from the book: "Geotextiles" by N.W.M. John, 1987, published by Blackie Glasgow and London.

In the known foundation structures is above the heads of the pillars or piles a flat, essentially horizontal geosynthetic drift tion relocated. The columns or foundation piles can be concrete columns or mortar columns, darning columns, ballast columns or the like. It is also known to arrange so-called head plates on the columns to reduce the clear span of the geosynthetic reinforcement. The full area The geoplastic reinforcement is built into the flat and flat or flat surface Expansion of the foundation structure and the compaction of the fill so charged that they give way between the pillars or the head plates of the low load-bearing building ground sags. The on the geosynthetic reinforcement forces are large in the reinforcement Tensile forces that cause the geoplastic reinforcement to expand. An equilibrium state arises as a result of the interaction of stress, elongation, sag, tensile force or membrane load-bearing capacity and a possible counter pressure of the ground.

The invention has for its object to a foundation structure create where the resilience of the geosynthetic reinforcement is the same Framework is increased or the reinforcement appears more efficient.

This object is achieved in that the heads of the Columns are formed by domed caps, the cross-sectional area of which Cross-sectional area of the pillars protrudes on all sides and their thickness from theirs  Steadily decreases towards the edge and one over these domed caps flexible geosynthetic reinforcement is laid in such a way that it keeps the bulge exercises in the area of the caps and the troughs between the caps follows and this already in the installation state, i.e. before the mobilization of Tensile forces by filling up soil.

However, the object underlying the invention can also be achieved in this way be that on at least two at regular intervals and parallel len rows arranged columns a domed bar is placed, the Thickness steadily from the center line to the two edges of the bar decreases and that about this at a distance from each other parallel to each other arranged bars a flexible geoplastic reinforcement is laid so that they are the bulges in the area of the bars and the Einmuldun between the bars follows.

Even before the geosynthetic reinforcement is laid, this creates Put on the domed caps or the domed bars, their lower page is located approximately at the level of the low-load building site, between troughs or valleys into which the flexible geoplastic reinforcement.

The domed caps or bars have a maximum height of 15 to 50 cm over their bottom. The prefabricated caps or bars can preferably made of concrete, reinforced concrete, plastic or cast iron hen. The caps or bolts can also be used as sheet steel-concrete Composite body can be formed, wherein a curved steel sheet or a curved sheet steel shell as a molded wall for the concrete to be filled serves. The steel sheet caps and the steel sheet shells are included in the Hollow-out punchings, welds, Embossing or the like provided to a reliable bond with to ensure the concrete to be filled. The caps can also be made from high-strength closed textile casings are formed, which preferably be filled with sand or concrete and thereby their curved shape receive.

The flexible, flexible geosynthetic reinforcement can be in the form of mats or tapes can be applied. The geomats can cover the whole area or  woven as a grid or as a layer of thread rustled on a fleece. The Geosynthetic reinforcement can consist of only one geomat, if their load-bearing threads are biaxially oriented. Is the reinforcement mat but provided only with threads carrying unidirectional load, then the geosynthetic reinforcement consists of at least two mats together that are laid so that their load-bearing threads are right-angled to each other. The reinforcement mesh can be with or without Intermediate floor layer.

Further features of the invention result from the following Description and from the claims.

In the following description, embodiments of the invention are described described in more detail with reference to the drawings. The painting show in:

Fig. 1 is a sectional view of a foundation structure according to the invention,

Fig. 2, the upper end of a column with the cap,

Fig. 3 perspective view of a round in plan cap,

Fig. 4 perspective view of a square in plan cap,

Figure 5 is perspective view. Of an arched bar,

Figure 6 is perspective view of a geosynthetic reinforcement mat having orthogonal, load. Supporting yarns in the laid over the curved caps state,

Fig. 7 a of FIG. 6 corresponding view of two geosynthetic reinforcement mats extend in only one direction load tra constricting threads in the laid over the curved caps state,

Fig. 8 is a view according to the section line VIII-VIII in Fig. 7,

Fig. 9 is a FIGS. 6 and 7 corresponding view of laid over the curved cap geosynthetic reinforcement bands

Fig. 10 perspective view of a cushion-like domed cap, which consists of a textile shell filled with sand or concrete.

Fig. 1 shows a sectional view of a foundation structure for a railway line, the reason 1 is guided over a not or only slightly stable construction. For the transmission of loads in the deep, load-bearing building ground 2 , foundation piles or columns 3 are arranged at regular intervals, which tower above the low-loadable building ground 1 . A geosynthetic reinforcement 5 is laid over the heads of the columns 3 , which is loaded with a fill 6 . The heads of the columns 3 are formed by curved caps 4 , the cross-sectional area of which extends beyond the cross-sectional area of the columns 3 on all sides and the thickness of which continuously decreases from their center towards the edge. A flexible geosynthetic reinforcement 5 installed so that it thereby follows the bulges in the region of the caps 4 and the trough configurations between the caps 4 - this caps 4 is - as well as Figs 6, 7 and 8.. Characterized in that the Geographic art fabric reinforcement 5 in cross-section and in longitudinal section wavy or sinusoidal extends, said shaft peaks are supported by the arched caps 4, significantly greater forces substantially flat laying can be collected than in the previously known from the geosynthetic reinforcement 5, this Geoplastic reinforcement.

Fig. 2 shows a placed on a column 3 cap 4 , which has on its underside a downwardly widening conical recess 9 into which an upwardly tapering projection of the support 3 protrudes. The height of the caps 4 from the bottom to the summit is essentially dependent on the distance between the columns 3 and can be 15 to 50 cm.

As shown in FIGS. 3 and 4 show, the domed cap 4 may be circular in plan view or be square. In any case, the curved cap 4 is designed so that no wrinkles and no major changes in direction arise when laying the geosynthetic reinforcement 5 .

It may be advantageous, instead of the domed caps 4, 4 'to provide 4 "curved lock 14 which are mounted on at least two columns each. 3 are advantageously arranged in parallel rows, the columns 3, so that the curved bar 14 transversely or longitudinally run to the traffic route and the geoplastic reinforcement 5 runs in the other direction in a wave shape.

In this version, geoplastic reinforcement is in the direction of Bolts not required, and the heavy-duty threads of the reinforcement only run across the bars.  

The domed caps 4 , 4 ', 4 "and the domed bolts 14 can in particular consist of concrete or reinforced concrete. The domed caps 4 , 4 ', 4 " can also be made of plastic or cast iron. Another embodiment of the caps 4 , 4 ', 4 "or bars 14 may consist in that they are composed of a curved sheet metal box or sheet metal shell which is poured out with a hardening material such as concrete. The curved sheet metal cap or sheet metal shell serves as a molded wall On this mold wall, inwardly protruding punchings, impressions or welded-on tabs or the like can be attached, which bring about a reliable bond between the sheet metal cap or sheet metal shell and the hardening material.

Fig. 6 shows a geosynthetic reinforcement mat 7 with orthogonally extending, load-bearing threads 10th Due to the flexibility, the elasticity and the certain displaceability of the threads 10 of the flat reinforcement mat 7 , this adjusts to the unevenness caused by the curved caps 4 , 4 ', 4 "almost without creases.

FIGS. 7 and 8 show a threaded through domed caps 4 Geographic art reinforcement fabric 5, which consists of two reinforcement mats 8 and 8 'whose load run in only one direction bearing threads 10. The two reinforcement mats 8 , 8 'are laid with or without an intermediate layer of sand or soil so that their load-bearing threads 10 run at right angles to one another.

Fig. 9 shows that part of the geosynthetic reinforcement can also consist of heavy-duty reinforcement bands 11 , 12 . These reinforcement bands 11 , 12 have the advantage that the reinforcement can be better adapted to the requirements and, for example, the resilience of the reinforcement can be made larger in one direction than in the direction at right angles to it. About these reinforcement bands 11 , 12 , a full-surface geosynthetic mat can be laid, the resilience speed is reduced and only serves to distribute the load on the reinforcement bands.

Usually, the foundation piles or columns 3 are arranged in a quadratic grid. In some cases, however, a triangular arrangement of the columns 3 is more advantageous. In such cases, the geosynthetic reinforcement 5 must also be designed triaxially. With the help of the reinforcement bands 11 , 12 , which are laid over the curved caps 4 of the triaxially arranged columns 3 , a rational tensile geoplastic reinforcement is possible.

In Fig. 10, the domed cap 4 '''is formed by a cushion-like shell 13 filled with sand or concrete. This textile cover 13 is a double fabric made of plastic threads, in which the two fabric layers are woven together on four edge strips 15 .

Reference list

1

low load-bearing ground

2nd

load-bearing building ground

3rd

pillar

4th

domed cap

4th

'domed cap, round

4th

"domed cap, square

4th

'''domed cap, pillow-like

5

Geoplastic reinforcement

6

Embankment

7

Geosynthetic reinforcement mat with orthogonal, load-bearing threads

8th

,

8th

'' Geoplastic reinforcement mat with unidirectional, load-bearing threads

9

Recess

10th

Load bearing threads

11

Reinforcement tape

12th

Reinforcement tape

13

Cover

14

arched latch

15

Edge strips

Claims (16)

1.Foundation structure on a low load-bearing building ground ( 1 ), in which columns ( 3 ) are arranged at regular intervals for the transmission of loads in the deep, load-bearing building ground ( 2 ), which tower above the low-loadable building ground ( 1 ) and A geosynthetic reinforcement ( 5 ) is laid over the heads of the columns ( 3 ) and is loaded with a fill ( 6 ), characterized in that ; that the heads of the columns ( 3 ) are formed by curved caps ( 4 ), the cross-sectional area of which projects beyond the cross-sectional areas of the columns ( 3 ) on all sides and the thickness of which decreases steadily from their center to the edge, and a flexible geosynthetic reinforcement ( 4 ) 5 ) is laid so that it follows the bulges in the area of the caps ( 4 ) and the troughs between the caps ( 4 ). 2. Foundation structure on a low load-bearing building ground ( 1 ), in which columns ( 3 ) are arranged at regular intervals and parallel rows for the transmission of loads in the deep, load-bearing building ground ( 2 ), the heads of the low load-bearing building ground ( 1 ) protrude and over the heads of the columns ( 3 ) a geosynthetic reinforcement ( 5 ) is laid, which is loaded with a fill ( 6 ), characterized in that an arched bolt ( 14 ) is placed on at least two columns ( 3 ), the Thickness decreases steadily from the center line to the two edges of the bar ( 14 ) and that flexible geo-plastic reinforcement is laid over these bars ( 14 ), which are spaced apart and parallel to one another, in such a way that the bulges in the area of the bars ( 14 ) and follows the trough between the bars ( 14 ). 3. Foundation structure according to claim 1 or 2, characterized in that the caps ( 4 ) or bars ( 14 ) have a maximum height of 15 to 50 cm above the level of their underside. 4. Foundation structure according to one of claims 1 to 3, characterized by prefabricated caps ( 4 ) or bars ( 14 ) made of concrete, reinforced concrete, plastic or cast iron. 5. Foundation structure according to claim 4, characterized in that the caps ( 4 ) or bars ( 14 ) are designed as a steel-concrete composite body, wherein a curved steel sheet cap or curved steel sheet shell serves as a mold wall for the concrete to be filled. 6. Foundation structure according to one of claims 1 to 5, characterized in that the caps ( 4 ) or bars ( 14 ) are provided on their underside with recesses ( 9 ), the cross section of which is somewhat larger than the cross section of the columns ( 3 ) , so that the caps ( 4 ) or bars ( 14 ) can be placed on the columns ( 3 ). 7. Foundation structure according to claim 6, characterized in that the upper end of the columns ( 3 ) and the recess ( 9 ) in the underside of the caps ( 4 ) or bars ( 14 ) are conical or tapered upwards. 8. Foundation structure according to claim 1, characterized in that the cap ( 4 ''') is formed from a pillow-like, textile cover ( 13 ) filled with sand or concrete. 9. Foundation structure according to one of claims 1 to 8, characterized in that the distance between the columns ( 3 ) from each other is 1.5 to 2.5 m and the diameter of the round caps ( 4 ) or the side length of square caps ( 4 ) or the width of the bars ( 14 ) is 0.5 to 1.40 m. 10. Foundation structure according to one of claims 1 to 9, characterized in that the underside of the caps ( 4 ) or bars ( 14 ) is located approximately at the level of the low-load building ground. 11. Foundation structure according to one of claims 1 to 10, characterized in that on the top of the cap ( 4 ) or bolt ( 14 ) fastening elements for the geosynthetic reinforcement ( 5 ) are arranged. 12. Foundation structure according to one of claims 1 to 11, characterized in that the geosynthetic reinforcement ( 5 ) is formed by at least one geotextile reinforcement mat ( 7 ). 13. Foundation structure according to claim 12, characterized in that over the caps ( 4 ) only in one direction larger loads (uniaxial) reinforcement mat ( 8 ) is laid and over this - with or without intermediate floor layer - a second uniaxial reinforcement mat ( 8 ' ) is installed with the load-bearing direction perpendicular to the first reinforcement mat. 14. Foundation structure according to claim 12, characterized in that to form the geosynthetic reinforcement approximately the width of the caps ( 4 ) correspondingly wide high-strength bands ( 11 , 12 ) over the grid of the columns ( 3 ) and caps ( 4 ) are laid and over this Bands ( 11 , 12 ) a full-surface reinforcement mat is laid. 15. Foundation structure according to one of claims 1 to 12, characterized in that the caps ( 4 ) provided columns ( 3 ) are arranged in a triangular pattern and the single- or multi-layer geotextile reinforcement with its load-absorbing threads is designed to be triaxial. 16. Foundation structure according to claim 15, characterized in that triaxial load transfer through at least three uniaxial geo-art Reinforcement layers are made, which are laid according to the triangular grid are.