RU2228479C1 - Method of reinforcement of loose grounds of bases and slopes (versions) and geo-grate for realization of this method - Google Patents

Abstract

FIELD: construction engineering; erection of pipe lines in slopes; building of roads and water-development works. SUBSTANCE: geo-grate laid on ground has cellular structure made from flexible bands fastened together in staggered order. Geo-grate is secured on ground at tension and its meshes are filled with loose material. Bands of geo-grate are made from soft materials kept in rolls; meshes of geo- grate are hexagonal in shape; fastening seams are twin; their strength is equal to strength of material of bands; distance between twin seams does no exceed half distance between inner seams of seam pairs which form meshes of geo-grate. Slopes whose steepness exceeds 45 deg. are reinforced with walls built up from horizontal geo-grates. Reinforcement is started from foot of slope and each subsequent layer is shifted towards slope partially penetrating into slope. EFFECT: avoidance of erosion of ground. 12 cl, 5 dwg

Description

The invention relates to the construction and is used in the construction of pipelines on the slopes, in the construction of long-distance driveways of trunk pipelines, in the construction of roads and hydraulic structures, where stability of soils is required. The prior art method for stabilizing soil against erosion, which consists in spraying the soil with an aqueous dispersion of a water-insoluble polyvinyl compound. A monolithic film is formed on the soil, preventing the destruction of the surface soil layer (see DE 1290007, 02.27.1969). The known method of protecting soils from erosion is applicable to agricultural land and is not effective for soils with vegetation.

It is known that the slopes of trenches and excavations are prone to landslides, especially during excavation and within two years after completion of work. It is well known that trenches, foundation pits of structures cut into loose soil and weathered rock at a depth of more than 1.25 m must have slopes or fastening in accordance with the nature of the bedrock, the conditions of their occurrence and hydrogeological conditions, while ensuring stability slopes during the time period designated by the project. A significant danger to pipelines crossing ravines and riverbeds is represented by landslides of the banks, exposing the pipeline and increasing its span, which can lead to deformation of the pipeline or its destruction.

It is known that during the construction of the West Ayad oil pipeline - the coast of the Gulf of Aden, on the section of the pipeline route through a sloping rocky desert and crossing the laid wadi channel, it was necessary to fill the crossing section with rocky soil using geotextile material, and the pipeline through temporary waterways was protected by gabion containers made of metal containers nets filled with rock fragments.

Thus, it is known that, for example, depending on the type of watercourses crossed by the pipeline route, various anti-erosion measures should be used. One of these activities is the use of geotechnical gratings to strengthen soils.

Known lattice textile mats designed to protect eroded soil layers, in particular slopes, dams and artificial embankments (see DE 4017710, 09.26.1991). The lattice mat is made in the form of a grid of strip-like textile structures forming shaped chambers of the chambers filled with bulk soil. However, the known technical solution is aimed at ensuring the connection of the external circuits of the individual lattice mats with a geometric closure with the formation of uniformly located recesses-chambers and does not contain a constructive solution of the lattice itself.

It is known from the prior art to use technical fabrics to protect the surface of slopes against erosion, blowing, to increase the bearing capacity of soils, since these materials have high tensile strength and good water permeability. Technical fabrics contribute to an even distribution of loads on the ground and improve water drainage. Technical fabrics include knitwear, cotton canvas and other natural and synthetic materials used in the construction industry for technical purposes (see REUTER F. et al. Engineering Geology, Moscow, Nedra, 1983, pp. 391-392, 417-418).

Known hardening housing for bulk and poured materials, used to strengthen earthworks, coasts, seabed, snow masses, etc., having a honeycomb structure consisting of separate solid or lattice strip-like elements with protrusions or spikes in the connecting seams and intended for fixing the device to the soil surface (see DT 3909189, 02/02/1989). The known device is material-intensive, difficult to manufacture and operate.

The prior art discloses a lattice made of textile tapes, the walls of which are formed by shuttlecocks obtained by joining the tapes with seams (see WO 97/16604 A1, 05/09/1997). The known device does not have the necessary strength at the joints of the tapes, and also does not have the necessary rigidity due to the lack of a fixed spatial geometrically homogeneous structure.

Known geotechnical lattice (geogrid) in the form of a volumetric cellular structure, designed to strengthen slopes, reinforce weak foundations in the transport, hydraulic and other construction industries. The geogrid is made of polyethylene tapes by welding them with linear seams staggered perpendicular to the base of the geogrid (see TU 2246-002-07859300-97 “PRUDON-494”, Plastic geotechnical grate). This solution is the closest to the claimed group of inventions and adopted as a prototype.

One of the disadvantages of the known solution is the insufficient lateral rigidity of the lattice, due to the high deformability of the polyethylene tapes, warping of their edges. In the known solution there is no equal strength welds and material of polyethylene tapes. When welding, there is a risk of embrittlement of the seam, tape, as well as the danger of burn-through.

In addition, the manufacture of geogrids by welding tapes made of polyethylene is associated with harmful emissions of volatile products of thermo-oxidative degradation into the air of the working area, it requires the organization of general ventilation and local exhaust, as well as protection against static electricity. Since polyethylene is a combustible material, serious fire safety measures are needed. Given that polyethylene is sensitive to solar radiation and exposure of the geogrid, for example, on a slope will lead to its rapid aging and destruction.

From all that has been said, there is the task of creating such a geogrid design so that it possesses the necessary mechanical strength, chemical resistance, and its production does not require special sanitary-hygienic and fire safety measures.

This problem is solved by the fact that in the method of reinforcing weak soils of foundations and slopes, consisting in laying on the ground having a honeycomb structure and made of stitching stitched together from a set of flexible geogrid tapes with its tension calculated force and fixing on the ground with subsequent filling the geogrid cells with bulk material, the geogrid stripes are made of soft rolled materials, and the geogrid cells are hexagonal, for which fastening seams are made paired - double and equally strong material of tapes, with a distance between double seams not exceeding half the distance between the internal seams of the pairs of seams forming the cells of the geogrid, while the surface of the soil prone to water erosion is reinforced with non-woven synthetic material (HCM) or a permeable technical fabric. In the particular case of the implementation of the method to prevent leaching of bulk material from the geogrid cells on the slopes, the ratio of the geogrid cell height to its diagonal coinciding with the slope direction is at least the slope of the reinforced slope.

When the slope of the reinforced slope is up to 30 degrees, technical fabric is used as a soft rolled material, and when the steepness of the reinforced slope is more than 30 degrees, polymer-fabric material is used as a soft rolled material.

A variant of the claimed invention is a method of reinforcing weak soils of foundations and slopes, which consists in laying on the ground having a honeycomb structure and made of stitching stitched together from a set of flexible geogrid tapes with its tension calculated force and fixing on the ground, followed by filling the geogrid cells bulk material, in which on slopes with a steepness exceeding 45 degrees, the slope is strengthened by walls from a set of horizontally located geogrid to, the reinforcement starts from the bottom of the slope and each subsequent layer is laid with a shift towards the slope, while the geogrids are laid with a partial insertion into the slope of adjacent geogrid cells and fixed in it, and the geogrid stripes are made of soft rolled materials, and the geogrid cells have the shape of the hexagon, the fastening seams are made in pairs - double and equally strong material of tapes, with a distance between double seams not exceeding half the distance between the inner seams of the pairs of seams, forming Geogrid cell constituents.

With a slope height of more than 2 m, a wall of geogrids is cut every 1.6-2 m in height into a reinforced slope to a depth of 200-400 mm and fixed in it. As a soft rolled material using technical fabric or polymer-fabric material.

In addition, the problem is solved in that the geogrid contains a set of flexible tapes stitched together in a checkerboard pattern perpendicular to the long sides of the flexible tapes with seams with the possibility of forming a cellular structure filled with bulk soil when laying a set of flexible tapes with their long ribs on the reinforced soil and the application of calculated transverse and longitudinal tensile forces to the extreme tapes with subsequent fixation on the soil of the cells around the perimeter of the stretched set of flexible tapes, and to increase stability, strength and peppermint stiffness geogrid flexible tape made of soft coiled material geogrid cells have a hexagonal shape, the fastening seams are paired - double and uniform strength material strips to the distance between the double seams, not exceeding half the distance between the inner seams pairs of seams forming the geocell cell.

In the particular case of geogrid execution, the outer tape in the set of flexible tapes is made double or from a material with higher mechanical properties and light fastness. In this case, the ratio of the cell height to its diagonal coinciding with the direction of the slope does not exceed the tangent of the angle of reinforced slope of the soil.

The invention is illustrated by graphic material, where Fig. 1 shows a geogrid in the initial position — as a packet of stitched ribbons; figure 2 - geogrid laid on the ground in the working (extended) position; figure 3 - connection diagram of the geogrid tapes, top view; figure 4 is an example of the use of geogrid on a steep slope; figure 5 - diagram of the calculation of the relations of the sizes of the cell geogrid.

Flexible tapes 1 made of soft rolled material are staggered stitched with transverse double seams 2 and 3, which are made perpendicular to the long sides of the tapes with their longitudinal ribs 4. A technical fabric suitable for strengthening soils on slopes up to 30 degrees is used as rolled material, which is used when ballasting underground pipelines. On slopes exceeding 30 degrees, a polymer-fabric material with a double-sided PVC coating is used.

These fabrics are high-strength, durable when used in soil and in the air, are well stitched with lowercase seams on industrial sewing machines. Stitching tapes is carried out with high strength threads. Folded geogrid is a rectangular block. The folded state of the geogrid is characterized by the absence of gaps (gaps) between its adjacent edges. Before fixing the geogrids on the ground, the latter can be sealed with passages of the tracked vehicle. The surface of the soil to be strengthened, prone to water erosion, may be lined with non-woven synthetic material (HCM) or a more durable and less deformable technical fabric, prior to fixing the geogrids, which protects the soil well from erosion and, being permeable, does not violate the hydrological regime of the area. The low deformability of the technical fabric ensures a stable position of the geogrid blocks on a slope. The high mechanical tensile strength of the technical fabric allows it to absorb weight from geogrids on long slopes, removing the load from the attachment pins and unloading geogrid blocks from the weight of neighboring blocks.

When deploying the geogrid block from the transport position to the working one, it is laid with ribs 4 on the ground in an extended position. The working position of the geogrid is characterized by the hexagonal shape of its cells. The rigidity of the geogrid in the working position is ensured by pair seams - doubling of ribbons 1 when double seams 2 and 3 are made, the distance between which does not exceed half the distance between the internal seams of 5, 6 adjacent pairs of seams that fasten the ribbons and form the geogrid cell. The stretched position of the geogrid is ensured by the application of design, not exceeding the tensile strength of the tapes or seams on the tear, transverse and longitudinal forces to the extreme tapes 7, 8 of the geogrid block. It is fixed on the ground with pins 9. The geogrid cells are filled with bulk soil, for example, with crushed stone, then the pins 9 are dismantled and used to fix another geogrid block on the ground. The ratio of the cell height to its diagonal coinciding with the direction of the slope should not exceed the tangent of the angle of reinforced slope of the soil. If you violate the specified ratio may expose the reinforced slope according to Fig.5.

When using LFM or technical fabric, the pins are driven into the ground through the panels of the lining material. To quench the flow rate of water under the geogrid when using LFM, the lower in the slope edges of the panels LFM should be inserted into the joint seam between adjacent blocks of the geogrids.

The technology of using geogrids on slopes of more than 45 degrees is as follows.

The reinforcement of the slope begins with the sole of the slope, on which the lower geogrid 10 is placed (see Fig. 4). Cells adjacent to the slope are partially cut into the slope and secured with pins. The geogrid is filled with drainage material, after which the next geogrid is placed on it with an offset towards the slope, fixed to the slope, and the geogrid cells are also filled with drainage material. With a slope height of more than 2 m and a steepness of slope of more than 45 deg, a wall from geogrids is cut every 1.6-2 m in height into a reinforced slope to a depth of 200-400 mm and fixed in it to unload geogrids and transfer the weight of the draining material to the ground slope.

Claims (11)

1. The method of reinforcing weak soils of foundations and slopes, which consists in laying on the ground having a honeycomb structure and made of a set of flexible geogrid ribbons stitched together by connecting stitches together with its tension and fixing on the ground, followed by filling its cells with bulk material, characterized in that the geogrid strips are made of soft rolled materials, and the geogrid cells are in the shape of a hexagon, for which the stitching seams are made in pairs - double and equally strong materials lu strips with the distance between the double seams, not exceeding half the distance between the inner seams pairs of seams forming the geocell cell. 2. The method according to claim 1, characterized in that the surface prone to water erosion of the soil to be strengthened is pre-lined with non-woven synthetic material (HCM) or a permeable technical fabric. 3. The method according to claim 1, characterized in that to prevent leaching of bulk material from the cells of the geogrid, the ratio of the height of the cell of the geogrid to its diagonal coinciding with the direction of the slope is not less than the slope of the reinforced slope. 4. The method according to claim 1, characterized in that when the steepness of the reinforced slope to 30 ° as a soft rolled material using technical fabric. 5. The method according to claim 1, characterized in that when the steepness of the reinforced slope is more than 30 °, polymer-fabric material is used as a soft rolled material. 6. The method of reinforcing weak soils of foundations and slopes, which consists in laying on the ground having a honeycomb structure and made of a set of flexible geogrid ribbons stitched together in a checkerboard pattern with its tension and fixing on the ground, followed by filling its cells with bulk material, characterized the fact that on slopes with a steepness exceeding 45 °, reinforcement of the slope is carried out by walls from a set of horizontally located geogrids, while strengthening begins from the bottom of the slope and each after the lining layer is laid with an offset towards the slope, and the geogrids are partially inserted into the slope of adjacent geogrid cells, the stripes of which are made of soft rolled materials, and its cells have the shape of a hexagon, for which the fastening seams are made in pairs - double and equally strong for the material of the ribbons with the distance between the double seams not exceeding half the distance between the inner seams of the pairs of seams forming the cells of the geogrid. 7. The method according to claim 6, characterized in that at a slope height of more than 2 m, a wall of geogrids is cut every 1.6-2 m in height into a reinforced slope to a depth of 200-400 mm and fixed in it. 8. The method according to claim 6, characterized in that the technical fabric or polymer-fabric material is used as a soft rolled material. 9. A geogrid containing a set of flexible tapes stitched together in a checkerboard pattern, perpendicular to the long sides of the flexible tapes with seams with the possibility of forming a cellular structure filled with bulk soil when laying a set of flexible tapes with their long edges on reinforced soil and applying transverse and longitudinal calculated tensile forces to the extreme tapes with subsequent fixation on the soil of the cells around the perimeter of the stretched set of flexible tapes, characterized in that to increase stability, strength and transverse stiffness of the geogrid, flexible ribbons are made of soft rolled materials, and the geogrid cells are hexagonal, for which the fastening seams are made of equal strength material of the ribbons and are doubled with a distance between the double seams not exceeding half the distance between the internal seams of the pairs forming the geogrid cells. 10. The geogrid according to claim 9, characterized in that the outer tape in the set of flexible tapes is made double or from a material with higher mechanical properties and light fastness. 11. The geogrid according to claim 9 or 10, characterized in that the ratio of the cell height to its diagonal coinciding with the slope direction is not less than the slope angle of the reinforced soil.

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