RU164791U1 - Geocell - Google Patents

Abstract

A geogrid obtained by longitudinal and subsequent transverse drawing from a pre-perforated sheet of polymer material and consisting of nodes connected each to the other six nodes by elongated ribs with oriented fibers ending in nodes, while the ribs located on opposite sides of each node are parallel to each other characterized in that parallel ribs located on opposite sides of each node and formed by longitudinal stretching are offset relative to each other about each other in the direction perpendicular to them.

Description

Technical field

The utility model relates to the field of construction, more precisely, to geogrids intended for use as a reinforcing and separating layer in the construction of the subgrade of linear transport (automobile, railway, pipeline) and geotechnical structures.

State of the art

Geogrids, in particular, polymer geogrids, are used to mechanically stabilize the soil in which soil particles (gravel, gravel) are held by the geogrid. If the lattice structure is correctly selected, the effect of jamming of soil particles in the geogrid occurs, while horizontal movement of artificial base particles is prevented. When dynamically acting on the soil, the geogrid prevents small particles of the soil base from moving upward and increases the resistance to shear of the underlying soil layer.

For the manufacture of a polymer geogrid, a blank is used - a sheet (tape) of polymer material. The workpiece is perforated, and then heated and pulled. As a result, perforations increase several times and are separated by ribs of oriented polymer material.

From US Pat. No. 3,386,876, published June 4, 1968, a geogrid is known that is obtained by longitudinal and subsequent transverse stretching during its manufacture from a pre-perforated sheet of polymeric material, and consisting of unstretched thickened nodes, each connected to other nodes by six elongated ribs with oriented fibers, ending in unstretched thickened nodes (in the nodes the fibers are not oriented and the oriented fibers in adjacent ribs are not a continuation of each other), while the ribs are located ennye opposite sides undrawn thickened node, parallel to each other, of which two ribs formed during transverse stretching are arranged without offset relative to each other in the longitudinal direction. This known geogrid is a prototype of the inventive geogrid.

The disadvantage of this geogrid is that the forces arising in the ribs during operation of the geogrid are directed to one point - the center of the elongated thickened node. This leads to the need to produce massive geogrids to increase their strength characteristics.

Disclosure of invention

The technical result achieved by the claimed invention is to increase the tensile strength of the geogrid due to the distribution in the elongated thickened nodes of the forces exerted on them by the ribs during operation of the geogrid.

The specified technical result is achieved in a geogrid obtained by longitudinal and subsequent transverse stretching during its manufacture from a pre-perforated sheet of polymer material, and consisting of nodes connected each other six nodes by elongated ribs with oriented fibers ending (interrupted) in nodes (i.e. E. at the nodes of the fiber are not oriented and the oriented fibers in adjacent ribs are not a continuation of each other), thickened in comparison with the ribs. In this case, the ribs located on opposite sides of the node are parallel to each other. Parallel ribs formed by longitudinal stretching are offset relative to each other in the direction perpendicular to them. And two ribs formed by transverse stretching are located without displacement relative to each other in the longitudinal direction.

As the polymeric material, for example, polypropylene or a copolymer of polypropylene can be used.

Brief Description of the Drawings

In FIG. 1 shows an image of a perforated sheet of polymer material.

In FIG. 2 and FIG. Figure 3 shows the influence of the location of triangular-shaped notches on the displacement of the ribs formed during longitudinal elongation relative to each other in the direction perpendicular to them.

In FIG. 4 shows an image of a longitudinally elongated perforated sheet of polymer material.

In FIG. 5 shows an image of the claimed polymer geogrid.

Utility Model Implementation

Since the receipt of the claimed geogrid is provided during its production, the following is a description of an example of how the claimed geogrid can be obtained.

Geogrid is made of polypropylene web (sheet) by perforation and orientation. The web formed on the calenders is fed to an electromechanical punch where holes are cut through the entire surface of the web. Perforation holes, for example, in the form of isosceles triangles, are arranged in rows across the sheet along straight lines coinciding with the bases of the triangular holes in the row. Rows consisting of triangular holes identically oriented along the sheet are arranged with a predetermined pitch a ₀ , as shown in FIG. 1. The triangular holes of each row alternate with the triangular holes of the other row oriented in the opposite direction.

In FIG. 2 and FIG. Figure 3 shows how the perforation holes 1, 2, 3, 4, 5, and 6 determine the shape of the assembly 7 and the location relative to the assembly of the ribs formed after the sheet is drawn from the polymeric material. From the comparison shown in FIG. 2 and FIG. 3, it can be seen that while maintaining the distance b ₀ between the rows oriented in opposite directions and decreasing the notch pitch from a ₀ in FIG. 2 to a ₁ in FIG. 3, it is possible to obtain nodes of a more elongated (elliptical) shape and a larger displacement value c ₁ in FIG. 3, compared with c ₀ in FIG. 2 formed by longitudinal elongation of parallel ribs relative to each other in a direction perpendicular to them.

Due to the offset c ₀ in FIG. 2 or c ₁ in FIG. 3 ribs located on opposite sides of the geogrid node, the efforts to break this node arising from the operation of the geogrid are distributed in this geogrid node. This increases the strength of the geogrid and reduces the likelihood of a geogrid rupture in its node.

After perforation, the perforated web enters the longitudinal orientation chamber, where it is heated to a temperature of 90-110 ° C and longitudinal stretching (uniaxial orientation). The resulting semi-finished product is shown in FIG. four.

After longitudinal orientation, the web is tucked into the lateral orientation unit. The installation is a chamber in which the semi-finished product is fed using two screw chains. The resulting geogrid is shown in FIG. 5, its nodes 7 and ribs 8. In FIG. Figure 5 shows that the ribs located on opposite sides of the geogrid assembly and elongated in one direction are parallel, but are offset from each other in the direction perpendicular to these ribs.

Claims (1)

A geogrid obtained by longitudinal and subsequent transverse drawing from a pre-perforated sheet of polymer material and consisting of nodes connected each to the other six nodes by elongated ribs with oriented fibers ending in nodes, while the ribs located on opposite sides of each node are parallel to each other characterized in that parallel ribs located on opposite sides of each node and formed by longitudinal stretching are offset relative to each other about each other in the direction perpendicular to them.

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