RU194938U1 - Reinforced geogrid - Google Patents

Abstract

The technical solution relates to the polymer industry, namely to geogrids (geogrids) made of polymeric materials. The technical result consists in increasing the reliability of the geogrid, by increasing the strength of the joints of its bands. The geogrid includes rows of strips 1 made of polymer material arranged in rows, having protruding above the surfaces of the strips of the corrugation geogrid 2, which form diamond-shaped cells 3 on the surfaces of the strips, and in each diamond-shaped cell 3 there is an additional diagonal rib 4, the ends of which are connected to nodes 5 of the diamond-shaped cells 3, each of the mentioned strips 1 along its length with a constant step is connected to adjacent strips by transverse seams 6, and each transverse seam 6 is formed by polymer welding of parts of the strips from in order to strengthen the transverse seam 6 on one of the strips ultrasonically welded from its outer side, rows of blind anchor recesses 7 are made, and on the other strip from its outer side in the region of the series of recesses there is an additional flattened reinforcement 8 formed by compressed-deformed under the influence of temperature, diamond-shaped cells, their nodes and diagonal ribs, which are fused between themselves and the outer smooth surface of the tape 9. 5 zp f-ly, 6 ill.

Description

The technical solution relates to the polymer industry, namely to geogrids (geogrids) made of polymeric materials and intended to strengthen slopes and foundations.

The prior art many geogrids of a similar geometric configuration RU 56901 U1, 09/27/2006; RU 146219 U1, 04.24.2014; RU 2129189 C1, 04.20.1999, EA 201690682 A1, 2016.08.31; US 2011217117 A1, 08/09/2011, US 2006147276 A1 06/06/2006; RU 2152480 C1, 07/10/2000; RU 2166025 C1, 04/27/2001.

The closest analogue to the claimed technical solution is a geogrid, which is a set of polymer ribbons interconnected by welded joints to form staggered cells, characterized in that the welded joints of polymer ribbons forming the extreme lattice cells are reinforced by additional means of connection (RU 99008 U1, 11/10/2010).

The disadvantage of the closest analogue is the use of additional connecting elements.

The closest analogue to the claimed technical solution is a device for strengthening the soil, containing, with the possibility of assembly in a bag, flexible strips made of a polyolefin or a mixture of polyolefins and the surface of which is structured with diagonal mesh corrugation in the form of rhombs, the flexible strips being interconnected using several rows spot welds of ultrasonic welding with the possibility of forming a geogrid when unfolding the package, in addition, at least two opposite corners of the rhombuses are mesh diagonal corrugations of interconnected corrugations additional element.

The technical problem and the disadvantage of the closest analogue are the insufficient strength of the connection of the strips using spot seams, performed exclusively by ultrasonic welding.

The technical result consists in increasing the reliability of the geogrid, by increasing the strength of the joints of its bands.

The technical result is achieved due to the fact that the reinforced geogrid includes rows of strips of polymer material having protruding above the surfaces of the corrugated geogrid strips, which form diamond-shaped cells on the surface of the strips, with an additional diagonal rib located in each diamond-shaped cell, the ends of each of which are connected to by nodes of rhomboid cells, each of the marked strips along its length with a constant step is connected to adjacent strips by transverse seams, each transverse seam formed by polymer welding of parts of strips of the aforementioned polymeric material, while for reinforcing the transverse seam on one of the strips ultrasonically welded on its outer side, rows of blind anchor recesses are made, and on the other strip on its outer side in the region of the series of recesses there is an additional flattened reinforcement, formed by compressed-deformed under the action of temperature diamond-shaped cells, their nodes and diagonal ribs, which are fused together and the outer smooth surface of the tape.

Advantageously, the additional flattened reinforcement formed by the diamond-shaped cells compressed by deformation under the action of temperature is made by rolling with a tool heated to the melting temperature of the polymer material with a smooth, preferably spherical surface.

Anchor recesses are made narrowing, preferably of a pyramidal or conical shape and are made by means of a polymer material of a tool heated to the melting temperature with two rows of protrusions forming recesses, each of which is less than the sum of the thicknesses of the two joined tapes, but not less than the thickness of one tape, while for the thickness the tape adopted the thickness of its base without regard to the height of the corrugation.

It is preferable that the depth of each anchor recess exceeds the thickness of the strip of polymer material, but is less than the sum of two thicknesses connected in the transverse seam of the two strips.

Preferably, the end portion of each recess is in a strip in the portion of which there is a flattened reinforcement.

Advantageously, the recesses are made tapering, preferably of a pyramidal shape, in the form of a truncated pyramid.

The technical solution is illustrated by drawings.

In FIG. 1 shows a geogrid decomposed from a plane transport state (isometric view).

In FIG. 2 shows an enlarged fragment of the surface of the strip of the geogrid with corrugation.

In FIG. 3 shows a fragment of the first strip of the geogrid, from the outside with which the anchor recesses are made.

In FIG. 4 shows a fragment of the second connectable strip of the geogrid, on the outside of which a flattened reinforcement (rolling) is made.

In FIG. 5 shows a flattened reinforcement in the transverse seam region of the second strip (isometric view)

In FIG. 6 shows the implementation of anchor recesses in the transverse seam (isometric view)

The reinforced geogrid (hereinafter referred to as the geogrid) includes rows of strips 1 made of polymer material arranged in rows, having corrugation 2 protruding above the surfaces of the strips of the geogrid, which form diamond-shaped cells 3 on the strip surfaces. The corrugations 2 are made on both sides of each geogrid strip.

In each diamond-shaped cell 3 there is an additional, preferably longitudinal diagonal rib 4, the ends of which are connected to the nodes 5 of the diamond-shaped cells 3.

Each of the mentioned strips 1 along its length with a constant step is connected to adjacent strips by transverse seams 6, and each transverse seam 6 is formed by polymer welding of parts of the strips from said polymeric material.

To strengthen the transverse seam 6 on one of the strips welded by ultrasonic welding, rows of blind anchor recesses 7 are made from its outer side.

At the same time, on the other strip from its outer side in the region of the rows of recesses there is an additional flattened reinforcement 8 formed by diamond-shaped cells that are compressedly deformed under the influence of temperature, their nodes and diagonal ribs, which are fused between themselves and the outer smooth surface of the tape 9.

An additional flattened reinforcement 8, formed by rhomboid cells compressedly deformed under the action of temperature, is made by rolling with a tool heated to the melting temperature of the polymer material with a smooth, preferably spherical surface.

The anchor recesses 7 are made tapering, preferably of a pyramidal or conical shape and are made by means of a polymer material of a tool heated to the melting temperature with two rows of protrusions forming the recesses, the length of each of which is less than the sum of the thicknesses of two joined tapes, but not less than the thickness of one tape, the thickness of the tape is the thickness of its base without taking into account the height of the corrugations.

The depth of each anchor recess 7 exceeds the thickness of the strip of polymer material, but is less than the sum of the two thicknesses of the two strips 7 connected in the transverse region of the seam, while the end part of each anchor recess 7 is in an adjacent strip, in the part of which there is a flattened reinforcement 8 (seal) .

Anchor recesses 7 are made tapering, preferably of a pyramidal shape, in the form of a truncated pyramid.

The device is made as follows. As a preform, we take canvases of a polymeric material made of a polyolefin, such as polyethylene or polypropylene, or mixtures thereof. The canvas is passed through a machine that forms corrugations 2 with diagonal ribs 4 on both sides of the canvas.

Next, cut the canvas into strips. The bands in the area of the seams 6 are fastened together by ultrasonic welding. Further, in the area of the seams 6, a flattened reinforcement (seals) and simultaneously anchor recesses are formed on one side of the seam by heating and pressure (rolling). Moreover, it is preferable that both of the last mentioned operations are performed simultaneously using a special tool or machine.

After temperature control of the transverse seams 6, the resulting device is stacked, placing strips close to each other. A stacked device can be rolled up. The resulting seams are particularly durable, and the absence of holes or perforations in the walls increases their tensile strength, which together significantly enhances the geogrid.

When installing the strip stretch in the transverse direction with the formation of cells 10, in which the soil is poured, gravel drank another loose filler.

Claims (6)

1. Reinforced geogrid, characterized in that it includes rows of rows of polymer material arranged in rows, having protruding above the surfaces of the corrugated geogrid strips, which form diamond-shaped cells on the strip surfaces, with an additional diagonal rib located at each diamond-shaped cell, the ends of which are connected to diamond-shaped nodes cells, each of the marked strips along its length with a constant step is connected to adjacent strips by transverse seams, and each transverse seam is formed by polymer welding ith parts of strips of the aforementioned polymeric material, while for reinforcing the transverse seam on one of the strips ultrasonically welded on its outer side, rows of blind anchor recesses are made, and on the other strip on its outer side in the region of the rows of recesses there is an additional flattened reinforcement formed by compressed - diamond-shaped cells deformed under the influence of temperature, their nodes and diagonal ribs, which are fused between themselves and the outer smooth surface of the tape. 2. The reinforced geogrid according to claim 1, characterized in that the additional flattened reinforcement formed by the diamond-shaped cells compressed by deformation under the influence of temperature is made by rolling with a tool heated to the melting temperature of the polymer material with a smooth, preferably spherical surface. 3. The reinforced geogrid according to claim 1, characterized in that the anchor recesses are made narrowing, preferably of a pyramidal or conical shape and are made by means of a tool heated to the melting temperature of the polymer material with two rows of protrusions forming the recesses, each of which is less than the sum of the thicknesses of the two joined tapes, but not less than the thickness of one tape, while the thickness of the base is taken as the thickness of the tape without taking into account the height of the corrugations. 4. The reinforced geogrid according to claim 1, characterized in that the depth of each anchor recess exceeds the thickness of the strip of polymer material, but is less than the sum of two thicknesses connected in the transverse joint area of the two strips. 5. Reinforced geogrid according to claim 1, characterized in that the final part of each recess is in a strip, in the part of which there is a flattened reinforcement. 6. The reinforced geogrid according to claim 1, characterized in that the recesses are made tapering, preferably of a pyramidal shape, in the form of a truncated pyramid.

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