RU2700359C1 - Volumetric geogrid for strengthening slopes - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction, namely, to volumetric geogrid structures, and can be used for slopes strengthening in oil and gas, transport, hydraulic engineering and other construction industries. Geogrid has at least one element formed by sheet of polymer material, in which there are slots of equal length, symmetry axes of which are parallel to each other, arranged in rows with offset of slots of adjacent rows relative to each other in longitudinal direction. Slots are made essentially in the form of sections of straight lines so that at movement of edges of each of slots in mutually opposite directions a cell is formed with front and rear walls, at that, at least one element is formed on the condition: 0.1≤d/h≤8, where d is distance between cell rear wall outer surface and cell front wall outer surface; h is distance between rows, in which slots have no displacement relative to each other.

EFFECT: technical result consists in improvement of geogrid strength to break while providing simplicity of its manufacture and efficient use.

12 cl, 5 dwg, 1 tbl

Description

The invention relates to the field of construction, namely, to the designs of volumetric geogrids, and can be used to strengthen slopes in the oil and gas, transport, hydraulic and other construction industries.

Known geogrid formed by strips of polymeric material connected to each other, so that when the geogrid is stretched, cells are formed that are filled with soil or granular material (see RU 2603677 C2, 11.27.2016).

A disadvantage of the known geogrid is the need to use polymer materials with increased strength for its manufacture, which is due to the possible bias, otherwise, such a geogrid down when used on an inclined surface under the influence of aggregate, which, in addition, can cause the destruction of the geogrid.

Known geogrid formed by a sheet of elastic polymer material in which slots are made in the form of slots (in particular, oval) of the same length, the axis of symmetry of which are parallel to each other, arranged in rows with offset slots of adjacent rows relative to each other in the longitudinal direction, thus that when the geogrid is stretched, cells form (see RU 2090702 C1, 09/20/1997). This known geogrid is the closest analogue of the claimed geogrid.

A disadvantage of the known geogrid is that the shape of its slots causes uneven thicknesses of the partitions between the cells formed as a result of stretching the geogrid, which leads to heterogeneity of the strength properties of the geogrid as a whole.

The technical problem solved by the claimed invention is to create a volumetric geogrid design, which is the optimal solution for strengthening the soil.

This achieves the technical result, which consists in increasing the tensile strength of the geogrid while ensuring the simplicity of its manufacture and efficient use.

The technical problem is solved, and the specified technical result is achieved by creating a geogrid containing at least one element formed by a sheet of polymer material, in which the slots are made essentially in the form of straight line segments of the same length, arranged in rows with offset slots of adjacent rows relative to each other in longitudinal direction, so that when you move the edges of each of the slots in mutually opposite directions, a cell is formed having a front and rear wall, and this mentioned at least one element is formed from the condition:

, где

where

d is the distance between the outer surface of the rear wall of the cell and the outer surface of the front wall of the cell;

h is the distance between the rows in which the slots have no displacement relative to each other.

The proposed design of the geogrid and the ratio between its parameters provide high strength properties of the geogrid as a result of achieving uniformity of the thickness of the partitions between the cells formed by the front and rear cell walls, as well as optimal cell sizes and, therefore, efficient use of the geogrid in the absence, at the same time, of uneven distribution stresses when stretching the geogrid. In addition, the proposed design of the geocell is easy to manufacture, since it does not require the use of high-tech methods and devices.

The technical problem is solved, and the specified technical result is also achieved in particular embodiments of the geogrid, according to one of which, said at least one element is formed from the condition:

, где

where

b ₀ is the length of each of the slots;

b is the longitudinal cell size.

In another particular embodiment, said at least one element is formed in such a way that the maximum tensile load at points of each cell spaced apart from each other by a distance equal to b is from 1 to 99 kN / m.

In yet another particular embodiment, the slots are provided with openings communicated with the ends of each of said straight line segments and symmetrical with respect to it, which further reduces the uneven distribution of stresses when stretching the geogrid.

In another particular embodiment, the aforementioned at least one element is perforated, which additionally allows water to be drained from the ground, reinforced with a geogrid.

In another particular embodiment, the surface of the sheet of polymer material is textured, which further improves the adhesion of the geogrid to the ground.

In yet another particular embodiment, high pressure polyethylene (HDPE) or low pressure polyethylene (HDPE) is used as the polymer material.

In yet another particular embodiment, the geogrid comprises at least two of said elements connected to each other by means of a welded or mechanical connection.

In yet another particular embodiment, openings are made in the sheet of polymer material to allow the placement of connecting elements therein.

In one of the preferred embodiments, said holes are located at the same distance from the ends of each of the slots and are symmetrical about its longitudinal axis.

In another preferred embodiment, said holes are located at the same distance from the end of each of the extreme slots and are symmetrical about its longitudinal axis.

In another preferred embodiment, said openings are round or oval.

Further possible embodiments of the invention are explained in detail with reference to the figures.

In FIG. Figures 1a and 1b show an image of a geogrid element, in various particular embodiments, before it is stretched (inoperative).

In FIG. 2 shows an image of a geogrid element, in a particular embodiment, after it has been stretched (in working condition).

In FIG. 3 shows an image of a geogrid cell.

In FIG. 4 shows an image of a roll of polymeric material from which geogrid elements can be formed.

An element of the inventive geogrid shown in FIG. 1a, 1b and 2, is formed by a sheet 1 of a polymeric material (for example, HDPE or HDPE), in which slots 2 of the same length b are made₀arranged in rows (R_one, R₂, ..., R_n) parallel to each other with offset slots of 2 adjacent rows (R_one and R₂, R₂ and R₃ etc.) relative to each other in the longitudinal direction. Sheet 1 is perforated and its surface textured.

As the polymeric material, any other suitable polymeric material may also be used, including, but not limited to, geotextile material, thermoplastic material, thermoplastic elastomer.

In a particular embodiment, the slots 2 are made in the form of segments of straight lines 2a and holes 2b communicated with the ends of each of the segments 2a and symmetrical with respect to it.

The execution of each of the slots 2 essentially in the form of a straight line segment ensures the location of the edges of the slots 2 with a minimum gap relative to each other, i.e. almost close to each other. This ensures that the thicknesses of the partitions between the cells are uniform and, as a result, the unevenness of the stress distribution during stretching of the geogrid is reduced. Slots 2 can be made by any suitable known method, including, but not limited to, mechanical, plasma, and laser cutting.

When the edges of each of the slots 2 are moved in mutually opposite directions, a cell is formed (see Fig. 3), having a front and rear walls, with a height equal to the distance h between the rows in which the slots 2 are not displaced relative to each other (between rows R ₁ and R ₃ , R ₃ and R ₅ , etc.). The geogrid element is formed from the condition:

, где

where

d is the distance between the outer surface of the rear wall of the cell and the outer surface of the front wall of the cell;

h is the distance between the rows in which the slots have no displacement relative to each other.

The upper boundary of the specified range is selected for reasons of avoiding stress concentration at the ends of the slots, leading to a decrease in the strength of the geogrid as a whole; the lower boundary determines the minimum possible extension of the geogrid element and, therefore, the size of each of the cells for its effective use.

Not necessarily, the element of the claimed geogrid is also formed from the condition:

, где

where

b is the longitudinal cell size;

b ₀ is the length of each of the slots.

The lower boundary of the specified range is also selected for reasons of preventing concentration at the ends of the slots of stress, leading to a decrease in the strength of the geogrid as a whole; the upper boundary determines the minimum possible extension of the geogrid element and, therefore, the size of each of the cells for its effective use.

In specific examples of execution, the geogrid element may have the parameters presented in the table.

Table

Options Value The distance between the rows in which the slots have no displacement relative to each other (h), mm 75, 100, 150 Longitudinal cell size (b), mm 255 302 320 390 450 88 The distance between the outer surface of the rear wall of the cell and the outer surface of the front wall of the cell (d), mm 211 282 300 372 432 74

Not necessarily, the element of the inventive geogrid is formed in such a way that the maximum tensile load at the points of each cell remote from each other by a distance equal to b is from 1 to 99 kN / m.

The upper limit of this range is chosen for reasons of maintaining the integrity of the geogrid design when using it to strengthen slopes of great steepness (more than 60 degrees) and to use concrete and similar materials as a filler when exposed to external loads, for example, ice. The lower limit of the specified range is selected for reasons of using a geogrid to strengthen gentle slopes (less than 20 degrees) in the absence of external loads, as well as using vegetable soil and similar materials as a filler.

A geogrid can be formed from two or more of the elements described above by means of a welded (for example, using ultrasonic welding) or mechanical (using metal clips or other suitable connecting elements) connection.

In particular, in the sheet 1 of the polymeric material, holes 3 can be made to ensure that the connecting elements are placed in them (see Fig. 1a and Fig. 1b).

In one embodiment, the holes 3, preferably round or oval, are located at the same distance from the ends of each of the slots 2 and are symmetrical about its longitudinal axis (as shown in Fig. 1a).

In another embodiment, the holes 3, preferably round or oval, can be made at the edges of the sheet 1 of polymeric material (as shown in Fig. 1b). The holes 3 in this embodiment are located at the same distance from the end of each of the extreme slots 2 and are symmetrical about its longitudinal axis.

As connecting elements, in particular, cables, plastic ties, metal wire (in the case of making holes round) or a mounting wrench (in case of making holes oval) can be used.

In this embodiment, the holes 3 of adjacent elements are combined with each other, and connecting elements are placed in them (for example, cables are threaded through them), which connect adjacent elements of the geogrid and simultaneously fix the geogrid on the ground.

Depending on the purpose, the geogrid cells are filled with various fillers, including, but not limited to, sand, gravel, peat mix, concrete.

The claimed geogrid is used, for example, as follows.

1. Prepare the soil of the sloping part of the subgrade, in particular, by a mechanized method with manual completion.

2. Place geogrid elements on the slope, for example, by unwinding a roll of polymer material, as shown in FIG. 4, fix them on top of the slope with anchors.

3. Bring the elements of the geogrid into working condition, stretching them.

4. Cut the elements of the geogrid to the desired length.

5. Fix the elements of the geogrid with anchors and connect them to each other, as described above.

6. Fill the cells with filler.

7. If necessary, sow perennial herbs.

Claims (18)

1. A geogrid containing at least one element formed by a sheet of polymeric material in which slots of the same length are made, the symmetry axes of which are parallel to each other, arranged in rows with offset slots of adjacent rows relative to each other in the longitudinal direction, characterized in that the slots are made essentially in the form of segments of straight lines in such a way that when the edges of each of the slots are moved in mutually opposite directions, a cell having a front and rear wall is formed, while said at least one element is formed from the condition:

where d is the distance between the outer surface of the rear wall of the cell and the outer surface of the front wall of the cell; h is the distance between the rows in which the slots have no displacement relative to each other. 2. A geogrid according to claim 1, characterized in that said at least one element is formed from the condition:

where b is the longitudinal cell size; b ₀ is the length of each of the slots. 3. A geogrid according to claim 1, characterized in that said at least one element is formed in such a way that the maximum tensile load at points of each cell spaced apart from each other by a distance equal to b is from 1 to 99 kN / m . 4. Geogrid according to any one of paragraphs. 1-3, characterized in that the slots are provided with holes communicated with the ends of each of the said segments of straight lines and symmetrical with respect to it. 5. Geogrid according to any one of paragraphs. 1-3, characterized in that the sheet of polymer material is made perforated. 6. Geogrid according to any one of paragraphs. 1-3, characterized in that the surface of the sheet of polymer material is made textured. 7. Geogrid according to any one of paragraphs. 1-3, characterized in that as the polymer material used high pressure polyethylene or low pressure polyethylene. 8. Geogrid according to any one of paragraphs. 1-3, characterized in that it contains at least two of the mentioned elements, interconnected by means of a welded or mechanical connection. 9. Geogrid according to any one of paragraphs. 1-3, characterized in that the holes in the sheet of polymer material are made to ensure that the connecting elements are placed in them. 10. The geogrid according to claim 9, characterized in that said holes are located at the same distance from the ends of each of the slots and are symmetrical about its longitudinal axis. 11. The geogrid according to claim 9, characterized in that said holes are located at the same distance from the end of each of the extreme slots and are symmetrical about its longitudinal axis. 12. The geogrid according to claim 9, characterized in that said holes are made round or oval.

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