RU106906U1 - REINFORCED GEOROGETS (OPTIONS) - Google Patents

Abstract

 1. A geogrid made of flexible polymer strips of a thermoplastic polymer material, preferably low and / or high pressure polyethylene, interconnected in parallel rows with a step along the length of the strip and staggered in adjacent strips of the joints connecting them, preferably welded, that upon stretching of the packet of strips installed on the end in the direction perpendicular to their plane, a lattice with diamond-shaped cells is formed, moreover, in the body, at least part of the strips, parallel to their longitudinal axis and with an offset from it to the most distant sides, are located, with the formation along the central longitudinal axis of a zone free of them, longitudinal reinforcing elements in the form of at least a pair of threads or rods of material, more tensile and / or with greater flexural rigidity than the polymeric strip material. ! 2. The geogrid according to claim 1, characterized in that the strips with reinforcing elements are located on opposite sides of the transverse axis of the geogrid, preferably in places of its design attachment to the base. ! 3. The geogrid according to claim 1, characterized in that in zones free of reinforcing elements, through holes or slots are formed in the strip, the axes of which are oriented parallel to the longitudinal axis of the strip or at an acute angle to it. ! 4. The geogrid according to claim 1 or 2, characterized in that the stripes forming it are made with a periodically increasing height, preferably in areas with the greatest possible deflection from the effect of the working load acting on it in the design position. ! 5. The geogrid according to claim 1 or 2, characterized in that the generators �

Description

The technical solution relates to the field of construction, namely, to geotechnical means of protection against erosion of engineering structures, to strengthen the slopes, strengthen the soil bases of roads, sites on soft soils and other structures.

Known geogrid, which is a set of polymer tapes interconnected by welded joints with the formation of cells arranged in a checkerboard pattern, moreover, the welded joints of polymer tapes forming the extreme cells of the lattice are reinforced with additional connecting means, for example, riveted, bolted, glue, and for The tape was manufactured using low, high or medium pressure polypropylene or polyethylene or a mixture thereof (RU No. 99008, ЕСС 5/00, 05/28/2010).

Geogrids made of polymer tapes (strips) of thermoplastic material, for example polyethylene, are widely known, interconnected in parallel rows with a certain pitch and with staggered seams, so that when the tape pack installed on the end faces is stretched in the direction perpendicular to the plane of the ribbons , a lattice with diamond-shaped cells is formed (see, for example, http://www.494unr.ru/ourmat/shema.html, 2010).

The closest known one is a geogrid made of tapes (strips) of polymeric material welded together into a packet with the possibility of formation of a mesh diamond-shaped structure when stretched in the direction perpendicular to the plane of the tapes (http://www.presto.ru/reviews/review /, 2010).

Known solutions suggest that the strength properties of the lattice tape in its cross section should be constant, which initially determines the use of sufficiently tensile materials. Perforation in such tapes significantly weakens its cross-sectional strength, and therefore, to eliminate this undesirable effect, an excessive (with a large safety factor) increase in the strength of the entire tape, i.e. and in the place where such holes are absent.

The technical task is to create a geogrid with different strengths along the cross section of the bands (tapes) that form it. Such gratings, due to the design of the strips (tapes), take into account the distributed loads acting on the strip, which cause tensile stresses in the upper and / or lower parts of the strip in the region of its edges, which are reinforced by the proposed solution.

This is achieved by the fact that:

- in one embodiment, the geogrid is made of flexible polymer strips of thermoplastic polymeric material, preferably low and / or high pressure polyethylene, interconnected in parallel rows with a step along the length of the strip and staggered in adjacent strips of the joints connecting them, preferably welded , so that upon stretching the packet of strips installed on the end in the direction perpendicular to their plane, a lattice with diamond-shaped cells is formed, moreover, in the body, at least part of the strips, is parallel The longitudinal reinforcing elements in the form of at least a pair of threads or rods made of a material more tensile and located along their longitudinal axis and with an offset from it to the most distant sides are located, with the formation of a zone free of them along the central longitudinal axis / or with greater bending stiffness than the polymeric strip material. At the same time, strips with reinforcing elements can be located on opposite sides from the transverse axis of the geogrid, preferably in places of its design fastening to the base. And in zones free of reinforcing elements, through holes or slots are formed in the strip, the axes of which are oriented parallel to the longitudinal axis of the strip or at an acute angle to it. The lattice-forming strips are made with a periodically increasing height, preferably in areas with the greatest possible deflection from the action of the working load acting on it in the design position. The lattice-forming strips are made with a periodically increasing thickness, preferably in the areas of its connection with another strip. The lattice-forming strips are made with a longitudinal inner and / or outer rib on its opposite surfaces, preferably at the edge of the strip. The longitudinal inner and / or outer rib is continuous or discontinuous along the length of the strip. The longitudinal inner and / or outer rib is made in the area of the longitudinal reinforcing elements. The inner and / or outer longitudinal rib can be intermittently intermittently from the outer or inner sides of the cell surface by an amount not less than the length of the rib on the other surface, preferably with overlapping rip fracture zones. The rib can be made of constant cross-section, preferably arched or trapezoidal, or made of variable cross-section with an increase to the longitudinal axis of the cell. At least part of these or other bands is made with corrugations deposited on their inner and / or outer surface.

- in another embodiment, the geogrid is made of flexible polymer strips of thermoplastic polymeric material, preferably low and / or high pressure polyethylene, interconnected in parallel rows by pairs of transverse joints spaced apart from each other, or at least made each equal in length the mentioned distance, a pair of longitudinal seams, preferably welded, with a step along the length of the strip and staggered in adjacent strips, so that when stretching the package mounted on the torus stripes in the direction perpendicular to their plane, a lattice with hexagonal cells is formed, and in the body, at least part of the stripes, parallel to their longitudinal axis and offset from it to the most distant sides, form a free zone along the central longitudinal axis from them, longitudinal reinforcing elements in the form of at least a pair of threads or rods of material more tensile and / or with greater bending stiffness than the polymeric material of the strip. At the same time, strips with reinforcing elements can be located on opposite sides from the transverse axis of the geogrid, preferably in places of its design fastening to the base. In zones free of reinforcing elements, through holes or slots are formed in the strip, the axes of which are oriented parallel to the longitudinal axis of the strip or at an acute angle to it. The lattice-forming strips are made with a periodically increasing height, preferably in areas with the greatest possible deflection from the action of the working load acting on it in the design position. The lattice-forming strips are made with periodically increasing thickness, preferably in areas outside the connection with another strip. The lattice-forming strips can be made with a longitudinal inner and / or outer rib on its opposite surfaces, preferably at the edge of the strip. The longitudinal inner and / or outer rib is continuous or discontinuous along the length of the strip. The longitudinal inner and / or outer rib is made in the area of the longitudinal reinforcing elements. The inner and / or outer longitudinal rib is periodically discontinuous from the outer or inner sides of the cell surface by an amount not less than the length of the rib on another surface, preferably with overlapping rip fracture zones. The rib can be made of constant cross-section, preferably arched or trapezoidal in shape. At least part of the strips is made with corrugations deposited on their inner and / or outer surface.

In Fig.1 shows a section along aa in Fig.3 (reinforced strip).

Figure 2 presents a variant of the geogrid with a diamond-shaped cell.

Figure 3 presents a variant with a hexagonal cell plan in plan.

The geogrid (FIG. 2) is made of flexible polymer bands 1 of a thermoplastic polymer material, preferably low and / or high pressure polyethylene. The strips 1 are interconnected in parallel rows with a step “T” along the length of the strip and staggered in adjacent bands of the joints connecting them 2. The seams are preferably welded, for example by spot welding or by any other known method. When stretching the package installed on the end of the strips 1 in the direction perpendicular to their plane (in the direction of the arrows in FIGS. 2 and 3), a lattice with diamond-shaped cells (figure 2) or hexagonal (figure 3) is formed. In the body, at least part of the strips 1, parallel to their longitudinal axis and offset from it to the most distant sides (as in FIG. 1), longitudinal reinforcing elements 3 are formed along the central longitudinal axis of the zone free of them in the form of at least a pair of threads or rods of a material that is more tensile and / or with greater bending stiffness than the polymeric material of strip 1. Moreover, strips with reinforcing elements can be located on opposite sides of the transverse axis of the geogrid, will prefer In fact, in places of its design attachment to the base. And in zones free of reinforcing elements, through holes 4 or slots can be formed in the strip, the axes of which are oriented parallel to the longitudinal axis of the strip or at an acute angle to it. The lattice-forming strips are made with a periodically increasing height, preferably in areas with the greatest possible deflection from the action of the working load acting on it in the design position. The lattice-forming strips are made with a periodically increasing thickness, preferably in the areas of its connection with another strip. The lattice-forming strips are made with a longitudinal inner and / or outer rib on its opposite surfaces, preferably at the edge of the strip. The longitudinal inner and / or outer rib is continuous or discontinuous along the length of the strip. The longitudinal inner and / or outer rib is made in the area of the longitudinal reinforcing elements. The inner and / or outer longitudinal rib can be intermittently intermittently from the outer or inner sides of the cell surface by an amount not less than the length of the rib on the other surface, preferably with overlapping rip fracture zones. The rib can be made of constant cross-section, preferably arched or trapezoidal, or made of variable cross-section with an increase to the longitudinal axis of the cell. At least part of these or other bands is made with corrugations deposited on their inner and / or outer surface.

When placing the geogrid on the base in the design position, i.e. fixed, the cells are filled with the required bulk material. At the same time, the material of the walls of the strip of the geogrid has the ability to deform under the influence of a load compaction of bulk material. The magnitude of the deformation of the strip by its height is different - in the upper and lower zones of the strip, the deformation is limited by reinforcing elements 3. The presence of ribs enhances the identified technical effect. The cross section of the ribs is optimized for perceived loads.

Claims (23)

1. A geogrid made of flexible polymer strips of a thermoplastic polymer material, preferably low and / or high pressure polyethylene, interconnected in parallel rows with a step along the length of the strip and staggered in adjacent strips of the joints connecting them, preferably welded, that upon stretching of the packet of strips installed on the end in the direction perpendicular to their plane, a lattice with diamond-shaped cells is formed, moreover, in the body, at least part of the strips, parallel to their longitudinal axis and with an offset from it to the most distant sides, are located, with the formation along the central longitudinal axis of a zone free of them, longitudinal reinforcing elements in the form of at least a pair of threads or rods of material, more tensile and / or with greater flexural rigidity than the polymeric strip material. 2. The geogrid according to claim 1, characterized in that the strips with reinforcing elements are located on opposite sides of the transverse axis of the geogrid, preferably in places of its design attachment to the base. 3. The geogrid according to claim 1, characterized in that in zones free of reinforcing elements, through holes or slots are formed in the strip, the axes of which are oriented parallel to the longitudinal axis of the strip or at an acute angle to it. 4. The geogrid according to claim 1 or 2, characterized in that the stripes forming it are made with a periodically increasing height, preferably in areas with the greatest possible deflection from the effect of the working load acting on it in the design position. 5. The geogrid according to claim 1 or 2, characterized in that the stripes forming it are made with a periodically increasing thickness, preferably at the sites of its connection with another strip. 6. The geogrid according to claim 1, characterized in that the strips forming it are made with a longitudinal inner and / or outer rib on its opposite surfaces, preferably at the edge of the strip. 7. The geogrid according to claim 6, characterized in that the longitudinal inner and / or outer rib is continuous or discontinuous along the length of the strip. 8. The geogrid according to claim 6, characterized in that the longitudinal internal and / or external rib is made in the area of the longitudinal reinforcing elements. 9. The geogrid according to claim 6, characterized in that the inner and / or outer longitudinal rib is periodically intermittent from the outer or inner sides of the cell surface by an amount not less than the length of the rib on another surface, preferably with overlapping zones of rip fracture. 10. A geogrid according to any one of claims 6 to 9, characterized in that the rib is made of a constant section, preferably an arcuate or trapezoidal shape. 11. A geogrid according to any one of claims 6 to 9, characterized in that the rib, preferably an arcuate or trapezoidal shape, is made of variable cross section with an increase to the longitudinal axis of the cell. 12. The geogrid according to claim 1 or 2, characterized in that at least part of the strips is made with corrugations deposited on their inner and / or outer surface. 13. A geogrid made of flexible polymer strips of a thermoplastic polymeric material, preferably low and / or high pressure polyethylene, interconnected in parallel rows by pairs of transverse joints spaced apart from each other, or at least made each equal in length to said distance , a pair of longitudinal seams, preferably welded, with a step along the length of the strip and staggered in adjacent strips, so that when stretching the package installed on the end of the strips in the direction and perpendicular to their plane, a lattice is formed with hexagonal cells, moreover, in the body, at least part of the strips parallel to their longitudinal axis and offset from it to the most distant sides, form a zone free of them along the central longitudinal axis , longitudinal reinforcing elements in the form of at least a pair of threads or rods of material that is more tensile and / or with greater bending stiffness than the polymeric material of the strip. 14. The geogrid according to claim 13, characterized in that the strips with reinforcing elements are located on opposite sides of the transverse axis of the geogrid, preferably in places of its design attachment to the base. 15. The geogrid according to claim 13, characterized in that in the zones free of reinforcing elements, through holes or slots are formed in the strip, the axes of which are oriented parallel to the longitudinal axis of the strip or at an acute angle to it. 16. The geogrid according to claim 13 or 14, characterized in that the strips forming it are made with a periodically increasing height, preferably in areas with the greatest possible deflection from the effect of the workload acting on it in the design position. 17. The geogrid according to item 13 or 14, characterized in that the stripes forming it are made with periodically increasing thickness, preferably in areas outside the connection with another strip. 18. The geogrid according to claim 13, characterized in that the strips forming it are made with a longitudinal inner and / or outer rib on its opposite surfaces, preferably at the edge of the strip. 19. The geogrid according to claim 18, characterized in that the longitudinal inner and / or outer rib is continuous or discontinuous along the length of the strip. 20. The geogrid according to claim 18, characterized in that the longitudinal inner and / or outer rib is made in the area of the longitudinal reinforcing elements. 21. The geogrid according to claim 18, characterized in that the inner and / or outer longitudinal rib is periodically discontinuous from the outer or inner sides of the cell surface by an amount not less than the length of the rib on another surface, preferably with overlapping zones of rip fracture. 22. A geogrid according to any one of claims 18 to 21, characterized in that the rib is made of constant cross-section, preferably arched or trapezoidal in shape. 23. The geogrid according to claim 13 or 14, characterized in that at least part of the strips is made with corrugations deposited on their inner and / or outer surface.