RU197972U1 - Geogrid - Google Patents

Abstract

The technical solution relates to the field of construction, namely, devices for strengthening and / or drainage of earthen, rocky, mixed or other bases, mainly slopes. The technical result consists in simplifying the design while improving the drainage of water. A geogrid, characterized in that it consists of two rows of intersecting polymer rods - the upper row and the lower row, and the rods are soldered to form an open cell shape whose geometrical dimensions exceed the thickness of the rod, while layers of non-woven polymer material are located on both sides of the grid, which are connected to polymer rods. 9 s.p. f-ly, 4 ill.

Description

The technical solution relates to the field of construction, and in particular to devices for strengthening and / or drainage of earthen, rocky, mixed or other bases, mainly slopes.

The reinforced drainage composite geotextile material is known from the prior art, including a matrix of non-woven filter material and reinforcing elements, characterized in that strips of unidirectional roving fiberglass are used as reinforcing elements, previously impregnated with thermoplastic adhesive, placed on the matrix along it with a constant pitch and bonded with matrix over the entire surface by exposure to temperature and pressure (RU 2103439 C1, E02D 17/18, 08/10/2002).

The closest analogue to the claimed technical solution is a reinforcing geo-layer, which is a geogrid containing a grid made of a roving rope coated with a protective layer, characterized in that it is provided with a non-woven or woven material fixed to the grid (RU 2186906 C1, E02D 17/18 , 08/10/2002).

A geocomposite for the subgrade of a transport structure, containing a geogrid and two layers of geotissue fixed on both its planes, characterized in that the geogrid is made with a three-level structure for placing its elements, in which the cells have dimensions that prevent the geotissue layers from closing when they are loaded (RU 61725 U1, Е01С 5/22, 03/10/2007).

A drainage geocomposite containing, with the possibility of twisting into a roll, a geogrid with a two-level structure for placing its elements forming the cells, and two layers of geotissue fixed on the planes of the geogrid, characterized in that at least one of the corners of the cells is provided with a partition, and the elements of the levels of the structure of the geogrid made in the form of trihedral prisms (RU 98428 U1, ЕВВ 11/00, 2010.10.20).

The closest analogue is a geogrid with upper layers of nonwoven material and round-shaped rods located between them US 7470094 B2, 12/30/2008. The disadvantages of the closest analogue is the increased stiffness of the grid, as well as the execution of the rods rounded, which causes the flow of moisture along the surface of the rods towards the lower layer and provides only minimal movement of moisture along the rod.

The technical problem is to increase moisture removal (water drainage).

The technical result is to improve the drainage of water.

The technical result is achieved due to the fact that the geogrid consists of two rows of intersecting polymer rods - the upper row and the lower row, and the rods are soldered to form a cell whose geometrical dimensions exceed the thickness of the rod, while layers of non-woven polymer material are located on both sides of the grid, which are connected to the polymer rods, while grooves are formed on the lateral surfaces of the rods along the entire length of the rods.

Layers of non-woven polymeric material are connected to each other and to polymer rods by resistance welding, preferably precision ultrasonic welding.

Ultrasonic welding is made in the form of rows of welds, preferably intermittent double seams.

Layers of non-woven polymer material are connected to the polymer rods by spot welding.

Both layers of nonwoven polymer material are connected to the polymer rods by rows of welds, preferably intermittent double seams.

The distance between the rows of double seams does not exceed the length of the seam, while the seams are preferably located offset from each other.

The non-woven polymeric material is a textile non-woven fibrous, preferably fleecy, or geotextile.

The rods are twisted and / or curved-wavy.

The rods are made of preforms having an initially rectangular section, while grooves are formed on the lateral surfaces of the rods, for example, in the form of recesses, grooves or recesses.

The rows of rods are laid at an angle to each other with the formation of a gap between the grids, while the height of the lattice formed by the rods is from 5-15 mm, and there are through holes in the joints of the rods.

The device is illustrated by drawings:

in FIG. 1 shows a fragment of a geogrid with a bent (detached) edge of a layer of non-woven polymeric material;

in FIG. 2 shows a fragment of a geogrid in plan;

in FIG. 3 shows a section of a geogrid at the junction points (nodes) of its rods;

in FIG. 4 shows an enlarged fragment of the space in FIG. 3.

The geogrid consists of two rows of intersecting, mainly parallel polymer rods - the upper row 1 and the lower row 2, and the rods are soldered to form a cell (open shape), the geometrical dimensions of which exceed the thickness of the rod, while layers 3 and 4 of non-woven polymeric material that is connected to the polymer rods.

Layers of non-woven polymer material are interconnected by resistance welding, preferably ultrasonic welding.

Layers of non-woven polymeric material can also be interconnected and with polymer rods by contact welding, preferably ultrasonic welding.

Ultrasonic welding is made in the form of rows of welds, preferably intermittent double seams. Ultrasonic welding connecting the layers of nonwoven material 3 and 4 and the rods 1 and 2 can be performed spot or discrete.

Both layers 3 and 4 of non-woven polymer material are connected to the polymer rods by rows of welds 5, preferably intermittent double seams. The distance between the rows of double seams 5 does not exceed the length of the seam, while the seams are offset relative to each other, which increases the strength of the connection and the reliability of the geogrid .

The non-woven polymeric material is a textile non-woven fibrous, preferably fleecy, or geotextile.

The rods 1 and 2 may be twisted and / or curved-wavy.

The rods 1 and 2 are made of preforms having an initially rectangular cross section, while during the manufacturing process the preforms are deformed so that grooves, grooves, recesses or recesses are formed on the side surfaces of the rods, preferably made along the entire length of each rod 1 or 2.

The rows of upper and lower rods 1 and 2 are laid at an angle to each other, preferably at an acute angle, to form a gap between the grids, while the height of the lattice formed by the rods is from 5-15 mm, preferably about 10 mm, with a height of one rod 5 mm As shown by the tests, it provides the most intensive water drainage. Moreover, at the junction of the rods there are through holes 6 to ensure the flow of water, that is, the grooves or grooves do not overlap completely, for which the connection of the rods 1 and 2 occurs along their edges (Fig. 4).

The manufacturing process of the geogrid consists of two stages.

First, a lattice is made of the rods by deforming rectangular blanks and making grooves or grooves on their surfaces, and welding the rows of rods 1 and 2, then using a roll system, a composition consisting of a formed lattice coated on both sides with a non-woven polymer material is passed through a welding machine. At certain intervals, the convectors are lowered onto the canvas, and using ultrasound, layers of non-woven polymer material are welded to the grid.

The device operates as follows. The device is laid on an inclined base and filled with soil or other loose building material. The non-woven polymer material of layer 1 mainly performs the function of filtering water and eliminates the ingress of soil into the device. A geogrid with one layer of non-woven material will perform only a filtering function, and water will not be drained intensively. When a non-woven material is soldered to the geogrid from both sides (Fig. 2), in general, the design performs two functions at once, namely, filtration and drainage (water drainage). The proposed geogrid, to which the nonwoven material is soldered on both sides, has a rod cross-sectional height of 4-6 mm. This provides the optimum height for intensive drainage of water, since if the height of the rod were less, then the amount of filtered water would be diverted less intensively.

The main drainage is carried out through grooves or grooves formed on the lateral surfaces of the rods, as well as due to the lower layer of non-woven polymer material laid on the base. To improve drainage through the rods, holes 6 are made in the places of their joints, which allow water to flow freely along the entire length of the rod. Also, drainage is carried out by the lower mesh 4, laid on the base.

Claims (10)

1. Geogrid, characterized in that it consists of two rows of intersecting polymer rods - the upper row and the lower row, and the rods are soldered to form a cell whose geometrical dimensions exceed the thickness of the rod, while layers of non-woven polymer material are located on both sides of the grid, which are connected to the polymer rods, while grooves are formed on the lateral surfaces of the rods along the entire length of the rods. 2. The geogrid according to claim 1, characterized in that the layers of non-woven polymer material are connected to each other and to the polymer rods by contact welding, preferably spot ultrasonic welding. 3. The geogrid according to claim 2, characterized in that the ultrasonic welding is made in the form of rows of welds, preferably intermittent double seams. 4. The geogrid according to claim 1, characterized in that the layers of non-woven polymeric material are connected to the polymer rods by spot welding. 5. The geogrid according to claim 1, characterized in that both layers of non-woven polymer material are connected to the polymer rods by rows of welds, preferably intermittent double seams. 6. The geogrid according to claim 5, characterized in that the distance between the rows of double seams does not exceed the length of the seam, while the seams are preferably located with an offset relative to each other. 7. The geogrid according to claim 1, characterized in that the non-woven polymeric material is a textile non-woven fibrous, preferably fleecy, or geotextile. 8. The geogrid of claim 1, characterized in that the rods are twisted and / or curved-wavy. 9. The geogrid of claim 1, characterized in that the rods are made of blanks having an initially rectangular section, while grooves are formed on the side surfaces of the rods, for example, in the form of recesses, grooves or recesses. 10. The geogrid of claim 1, characterized in that the rows of rods are laid at an angle to each other with the formation of a gap between the grids, while the height of the lattice formed by the rods is from 5-15 mm, and there are through holes at the junction of the rods.

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