CZ2009467A3 - Geosynthetic grid - Google Patents

Abstract

The solution is a geosynthetic grid, where at least one part of the tape (2) that forms the grid is arranged at least on one side with stabilizing blades (3). The bits (3) are an integral part of the tape (2) or are firmly attached to the bands (2), e.g. by gluing or thermally, and are oriented in the working position perpendicular to the surface of the tape (2).

Description

Technical field

The invention relates to geosynthetics as a layer used for the consolidation of the ground.

BACKGROUND OF THE INVENTION

The importance of geosynthetics in the earth body has long been known for construction practice. In addition to the function of separation, drainage, filtration, protection, surface erosion protection, the reinforcing function also applies. Geosynthetics reinforced embankments of road and railway bodies are widely used applications of the reinforcing function of geosynthetics. The reinforcement function of geosynthetics, conceived as a tool for increasing the bearing capacity of a low-bearing subsoil mentioned in the literature, is in some cases inconclusive. This may therefore be the aforementioned separation function of geosynthetics, where the individual layers of the earth body act not as a whole, but as independent separated layers. It is generally known that the deflection of a structure is dependent on the moment of inertia of the structure. In the case of individual layers, the moment of inertia is always lower than the moment of inertia of one layer with a thickness equal to the sum of the thicknesses of the individual separated layers.

From US 4,472,086, a geogrid is known in which the fibers are wrapped in one direction, i.e. in the longitudinal or transverse direction, additionally wrapped with another fiber which forms loops at the nodes. This achieves roughening of the entire surface, but such technology is laborious and the roughening effect is not sufficient.

A geogrid is known from EP 1 458 912 B1, in which the fibers consist of a braid made of a plurality of fibers and, in places, the knots then have the shape of enlarged spherical elements. This achieves roughening of the entire surface, but such technology is laborious and the roughening effect is not sufficient. Similarly, the lattice is solved in DE 4123055.

A geogrid is known from EP 0 333 576 B1 in which the fibers are formed by strips and in one direction the strips are twisted and form spindle sections. As a result, the part of the strips k is oriented towards the plane of the geosynthetics. However, such production is demanding and increases the volume of rolls of rolled geogrid.

«T 2 9 9 9 9 9 9 9 ♦ 9 2 2 2 2 2 2 2 2 2 2 2 2 2 * ·· «« · ·

It is an object of the present invention to provide a geosynthetic lattice which comprises a sufficiently large transverse element to stabilize the lattice on a soft fine-grained substrate, but to prevent the transverse element from interfering with the roll and increasing the roll volume.

SUMMARY OF THE INVENTION

The aforementioned drawbacks are largely eliminated by the geosynthetic grid with stabilizing blades according to the invention, characterized in that at least a portion of the strips forming the grid are provided with stabilizing blades which are integral with the strips or are fixed to the strips on at least one side. attached, e.g., by gluing or thermally, and which are oriented in a working position perpendicular to the surface of the strips. This ensures the stability of the geogrid on the soil.

In a preferred embodiment, the blades are arranged to be uninterrupted only on the longitudinal or transverse strips of the warp.

In a further preferred embodiment, the blades are discontinuous and interrupted in the region of the warp nodes. Such a geogrid can then be easily wrapped into bales.

Overview of the drawings

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic view of one eye of a geosynthetic lattice with stabilizing cutting edges of the invention; Figure 2 is an enlarged detail of a section AA of the lattice strip of Figure 1 with the blade in working position; same detail, but with cutting edge in transport position.

DETAILED DESCRIPTION OF THE INVENTION

The geosynthetic lattice object of the invention is of synthetic material, e.g. polyester. Fig. 1 is a schematic view of one eye 1 from a warp of a geosynthetic lattice with stabilizing edges 3 in a top view. Each eye 1 consists of a pair of longitudinal strips 2 perpendicular to them a pair of transverse strips 2. The shape of the eye 1 need not be square, but may be any suitable shape. The transverse and longitudinal strips 2 are connected to one another in a known manner, or the entire geogrid can be formed by pressing, for example, from a geomembrane. In both cases, the longitudinal and transverse strips 2 meet at the nodes 4.

Stabilizing blades 3 are arranged between the individual nodes 4. The stabilizing blades can be made either as part of the longitudinal or transverse strip 2 - in the case that the geosynthetic is formed by additional joining of the longitudinal and transverse bands 2 in the nodes 4 or the strips are additionally attached, eg by gluing or thermally, - in the case that the geogrid is formed as a whole by pressing from a solid sheet element, eg geomembranes. This is best seen in Fig. 2, which is a cross-section of the strip 2 and the lip 3. It can be seen that the lip 3 is arranged substantially perpendicular to the surface of the strip 2.

As shown in detail in the cross-section of FIG. 3, the lip 3 of the geo-lattice lattice in the rolled-up state is pressed by the lattice layer above it onto the surface of the strip 2. made. The geogrid is then deposited on the soil with upright and activated blades 3 towards the soil and subsequent rolling with the blades 3 cut into the surface and stabilize the position of the entire geogrid against undesirable slip and displacement.

In order for the blades 3 to be pressed as far as possible onto the warp strip 2 in the rolled-up transporting state, it is advantageous if the blades 3 are discontinuous and do not extend up to the nodes 4 so that they do not interfere with each other.

The solution to the non-co-operation of a low-load-bearing fine-grained subsoil (generally ΕςΜ, 2 <10 MPa) reinforced by a geosynthetic according to the invention consists in the application of a geosynthetic equipped with blades 3 to embed the geosynthetic into said subsoil. These blades 3 are part of the geosynthetic, in this case geogrid, and are made of the same or different material as the geosynthetic. In a state where the geosynthetic is wound in a roll during malting or transport, the blades 3 are folded so that they are adhered to the plane of the bands 2 of the geosynthetic. When applying geosynthetics to the ground, the blades 3 are straightened so that they are at right angles to the plane of the bands 2. When placing the geosynthetic, the blades 3 will sink into the subsoil and thus ensure the interaction of the geosynthetic with the subsoil. Substrate layers of roadways, layers of railway substructure etc. are deposited on the geosynthetic in the usual way.

Claims (3)

PATENT CLAIMS Geosynthetic lattice, characterized in that on at least a part of the strips (2) forming the lattice, stabilizing blades (3) which are an integral part of the strips (2) or are fixed to the strips (2) are arranged on at least one side attached, for example by gluing or thermally, and which are oriented in the working position perpendicular to the surface of the strips (2). Geosynthetic grating according to claim 1, characterized in that the cutting edges (3) are arranged to be uninterrupted only on the longitudinal or transverse strips (2) of the warp. Geosynthetic grid according to claims 1 and 2, characterized in that the blades (3) are discontinuous and interrupted in the region of the warp nodes (4).