RU2180030C1 - Geomat - Google Patents

Abstract

FIELD: civil engineering, applicable for protection of slopes of roads, water-development works against erosion, as well as for reinforcement of soil beds of roads, airfields and other geotechnic objects. SUBSTANCE: the cellular structure geomat is made of two flexible strips installed on the ribs and interconnected by staggered linear joints. Novelty is in the fact that the strips are manufactured of unwoven geotextile reinforced by finishing and plain seams arranged uniformly over the area of strips and parallel to their base, the distance between the seams and the width of the stitch make up 2 to 5 mm, the strips are interconnected by plain seams with reinforcement of the edge zones. EFFECT: reduced specific consumption of materials, enhanced service life, strength, stiffness and water permeability of the cellular structure in the conditions of action of the soil medium. 6 cl, 4 dwg

Description

 The invention relates to the field of construction and can be used to protect against erosion of road slopes, hydraulic structures, as well as for reinforcing soil bases of roads, airfields and other geotechnical objects.

 A device for strengthening soils in the form of a geogrid of a cellular structure made of flexible polymer strips interconnected by welds in such a way that when tensile they form a cellular structure (see US patent 4717283, class B 32 V 3 // 2, 1988 .). The known technical solution has a high material consumption, since it is made of continuous polymer strips. In addition, the cell walls are solid waterproof, which violates the natural hydrological conditions and the filtration of water down the slope. The root system of plants is to some extent isolated by the borders of the cells, which prevents the formation of a stable turf cover on the protected surface.

 Known geogrid with a cellular structure to strengthen the soil surface, made of flexible perforated polymer strips mounted on the ribs and connected to each other in a checkerboard pattern with welds. The perforation of the strips is made discrete with the hole size from 3 to 16 mm, and the perforation pitch in the longitudinal and transverse directions is from 15 to 70 mm (see RF patent 2136817, class E 02 D 17/20, 1999). However, the cell walls of the known device are weakened by holes and therefore have insufficient crushing stiffness and tensile strength. In addition, the size of the holes is one to two orders of magnitude larger than the size of the soil grains, which can lead to suffusion (leaching) of soil from the cells through the holes in the walls and the development of erosion on the protected surface.

 Also known is a honeycomb geogrid made of strips of geotextile material installed on the ribs and interconnected by glue seams arranged in a checkerboard pattern. After pulling the bag in the direction perpendicular to the plane of the strips, a three-dimensional mat with hexagonal cells is formed (see RF patent 2111122, class B 32 B 3/12, 1993). It should be noted that the operation of gluing strips at a given accuracy is quite difficult to implement and, at the moment of stretching the glued packet, tissue can be torn off in separate places due to local gluing defects. In addition, adhesive joints are subject to aging, which reduces the durability of the structure.

 The closest technical solution (prototype) is a honeycomb geogrid with hexagonal cells made of non-woven thermally bonded geotextiles by connecting strips with stitched seams located in a checkerboard pattern (see Erosion protection for landscape construction. Akzo Nobel, 1995). However, the known geomat has insufficient rib stiffness and tensile strength of the strips and high tensile strength of the strips under load due to the fact that the strips are formed of synthetic fibers bonded to each other by a thermal contact method. In addition, in the soil environment under the influence of hydrogeological factors, the fiber structure of the strips can be delaminated (destroyed), which reduces the durability of the construction of reinforcing slopes.

 The problem to which the present invention is directed, is to reduce material consumption, increase the service life, strength, stiffness and permeability of the honeycomb structure under conditions of exposure to the soil environment.

 The problem is solved due to the fact that in the geomat of a honeycomb structure made of flexible strips mounted on the ribs and interconnected by linear stitches arranged in a checkerboard pattern, the strips are made of non-woven geotextiles, reinforced with sizing and stitched seams arranged uniformly in area and parallel to the base of the strips, while the distance between the seams and the width of the stitch is 2-5 mm.

 Also, geotextile strips can be made of high-strength synthetic fibers, for example polyester, and reinforced with sizing and stitched straight or zigzag seams.

 Also, geotextile strips can be made of natural fibers or a mixture of natural and synthetic fibers and strengthened by sizing and (or) stitched straight or zigzag seams.

 Also, geotextile strips can be strengthened by sizing and (or) a canvas-stitching method of bonding fibers by weaving "leotards" or "chain".

 Also, in all cases of hardening of geotextile strips, sewn seams are made with high-strength synthetic threads, for example polyester, with a thickness (linear density) of 4.5 to 18.1 tex.

 The problem is also solved due to the fact that the connection of adjacent strips between themselves is made by one or more rectilinear or zigzag stitched seams with reinforcement of the edge zones. In this case, the seams are made of high-strength synthetic thread with a thickness of at least 15.6 tex, and the reinforcement of the edge zones with a width of 1-3 cm is made by triple firmware. The dimensions of the geomat in the extended state are: length from 8 to 15 m, width from 1 to 15 m, height from 0.05 to 0.2 m, cell width from 0.2 to 1.0 m.

The invention is illustrated by the description and drawings, where:
figure 1 shows a General view of a fragment of a geomat in a folded (transport) state;
in FIG. 2 is a top view of a fragment of a geomat in a stretched (working) state;
figure 3 is a view A in figure 1 (arrangement of stitched reinforcing seams in the strip of geomat);
in Fig. 4 is a view B in Fig. 2 (arrangement of a stitched seam connecting adjacent stripes of a geomat).

или форму неправильного шестигранника.The geomat is a package 1 (Fig. 1) made of flexible geotextile strips 2 installed on the ribs and connected to each other in a checkerboard pattern by vertical stitched seams 3, which ensure that when stretching the strips in the direction normal to the surface of the strips, the honeycomb structure 5 ( figure 2) with cells of a hexagonal shape 6. The cells can be in the form of a regular hexagon with side a and width

or the shape of an irregular hexagon.

The flexible strips from which the geomat is made are non-woven needle-stitched or thermally bonded geotextile tapes with a thickness of δ = 1-5 mm and are made primarily of high-strength synthetic fibers, for example polyester. The discrete porous structure of the strips provides low material consumption and high permeability of the structure. So, for example, the mass of the geomat, thickness H = 10 cm and the side of the cell a = 20 cm, is ~ 0.25 kg / m ² . The mass of the corresponding honeycomb structure of the Geoweb type made of continuous polyethylene strips is ~ 1.7 kg / m ² .

 For regions with a warm and humid climate, when a powerful turf cover is formed on the protected surface in a fairly short time (within 1-2 years), it is advisable to produce geomats from geotextile strips made of natural or a mixture of natural and synthetic fibers. In this case, in the initial period, the surface from erosion is protected by geomat cells filled with plant soil. As the root system of plants develops, the turf cover takes on the function of erosion protection, and the walls of the geomat cells, decaying, serve as a kind of soil fertilizer.

 In order to increase the strength and stiffness of the cells, the geotextile strips are applied, i.e. impregnated with a special chemical composition based on acrylic latexes and / or stitched evenly over the area with stitched straight or zigzag seams 4 made with high-strength synthetic thread (Figs. 1, 3). Seams 4 are parallel to the base of the strips. The studies, as well as practical experience have shown that the following sizes will be optimal: stitch length 7 in each stitch = 2-5 mm, distance between stitches k = 2-5 mm. In this case, the seams are made of high-strength synthetic yarn, for example polyester fibers, with a linear density of 4.5 to 15.6 tex.

 Geotextile strips can also be made by the sewing method of bonding fibers by weaving “leotards” or “chains” and fitting.

 In order to form a cellular hexogonal structure of the geomat, the geotextile strips 2 are interconnected in pairs by linear vertical seams 3 with a shift in size a (Figs. 1, 2). With this method of geomate execution, each cell (except for the edge ones) has two opposite sides of double thickness 2δ (cd side, Fig. 2), which provides increased stiffness of the cells for crushing when laying soil material in them. In addition, the double walls of cd cells represent a pocket that can be used to securely install anchors that fix the geomat on an inclined soil surface.

 To connect adjacent strips, straight (chain) or zigzag seams 3 are used (Fig. 4). Seams are made using high-strength synthetic filaments, for example, of polyester fibers with a thickness of at least 15.6 tex. The optimal stitch width r (pos. 9) is from 2 to 5 mm.

 The edge sections of the connecting seams are most loaded, especially during the laying process and compaction of soil material. In these areas, the seam can spread, therefore, the edge zones of the seam are reinforced with brackets 8 in the form of triple firmware. The width of the weld reinforcement zone p is selected proportional to the height of the geomat (~ 0.1-0.2) N and ranges from 1 to 3 cm.

 The geomat is delivered to the construction site in the folded (transport) state in the form of a compact package 1 (Fig. 1), consisting of many flexible geotextile strips 2 installed on the ribs and connected together in a checkerboard pattern along their length with vertical seams 3. Selection of porous geotextile materials reinforced uniformly in area with stitched seams and (or) sizing, the connection of strips between themselves with stitched seams of high-strength synthetic thread with reinforcement of edge zones 1-3 cm wide allows 3-5 times lower erialoemkost design, improve water permeability, strength and rigidity Geomat cells compared to the base object. Due to the flexibility, compactness and low material consumption of the structure, it is possible to increase the size of the geomat in plan to 15 • 15 m, which is 3-5 times larger than the base object (Geoweb geogrid manufactured by Presto Product, USA has dimensions 2.43 • 6.1 m). Due to this, the number of butt joints of the geomat modules together decreases, and greater equal strength construction of the slope reinforcement is ensured.

где k_п=1,2-2,0 - коэффициент упаковки полос;
n - количество геотекстильных полос в пакете;
m - число ячеек в поперечном направлении геомата;
δ = 1-5 мм - толщина геотекстильной полосы;

ширина ячейки в продольном направлении;
a - длина стороны шестигранной ячейки.When performing reinforcing work, the geomat is installed on a pre-planned and compacted slope surface and stretched into working condition in size A • B (figure 2). The dimensions of the geomat in extended and folded states are related by the following relationships:

where k _p = 1.2-2.0 is the packing coefficient of the bands;
n is the number of geotextile bands in the package;
m is the number of cells in the transverse direction of the geomat;
δ = 1-5 mm - the thickness of the geotextile strip;

cell width in the longitudinal direction;
a is the side length of the hexagonal cell.

 The stretched geomat is fixed on the surface to be strengthened by means of L-shaped anchors installed through the pockets of cd (Fig. 2) cells into the soil base. To ensure the geometric shape of the geomat and its reliable fastening on the slope, the anchors are installed evenly around the perimeter with a step of 0.5-2.0 m and an area with a step of 1.0 - 3.0 m of the module. In a similar way, the following geomats are installed close to the first, connecting them with each other and with the soil base with L-shaped anchors. After that, either soil material or crushed stone, gravel, sand-gravel mix or concrete is laid in the cells, depending on the purpose of the geotechnical object. In the construction of reinforcement, the material-filler cells perceives compressive loads, and the cell walls perceive tensile (shear) stresses. External loads are distributed evenly over the surface to be strengthened due to anchors and meshing of the cell faces onto the soil base. The implementation of geomat cells from porous geotextile material provides reliable filtration of water down the slope.

 Thus, the proposed technical solution for the combination of distinctive features meets the criteria of "significant differences" and "novelty." The invention meets the eligibility condition "industrial applicability", since it is feasible using well-known means of production and technology.

 Practical work experience has shown that a cellular geomat of geotextile strips connected together in a checkerboard pattern by means of vertical stitched seams is a reinforcing tool for strengthening slopes, road and airfield bases and other geotechnical objects. Geomat has low material consumption, increased cell rigidity and strength of the joints and provides reliable protection of the soil from erosion and filtering water down the slope. The use of a geomat makes it possible to provide immediate protection of the soil surface from erosion, to significantly increase the service life of the construction of reinforcing slopes and foundations and to increase its bearing capacity under conditions of exposure to the soil due to: the optimal composition of the geotextile material of the strips reinforced by sizing with acrylic latex and (or) stitched seams with their optimal location in area and optimal parameters of stitched seams; optimal parameters of stitched seams connecting adjacent geomat stripes and made with reinforcement of edge zones; optimal cell sizes, providing high-quality compaction of soil material, and optimal module sizes, ensuring its reliable anchoring on the reinforced surface with a minimum length of the butt zones.

Claims (6)

 1. Geomat honeycomb structure made of flexible strips mounted on the ribs and interconnected by linear stitches located in a checkerboard pattern, characterized in that the strips are made of non-woven geotextiles, reinforced with sizing and stitched seams located uniformly over the area of the strips and parallel to them the base, while the distance between the seams and the width of the stitch is 2-5 mm, while the connection of the strips between themselves is made by one or more stitched seams with reinforcement of the edge zones.  2. The geomat according to claim 1, characterized in that the geotextile strips are made of synthetic fibers and reinforced with sizing and rectilinear or zigzag stitched seams.  3. The geomat according to claim 1, characterized in that the geotextile strips are made of natural fibers or a mixture of natural and synthetic fibers and are reinforced with sizing and straight or zigzag stitched seams.  4. The geomat according to claim 1, characterized in that the geotextile strips are made by a stitching method of bonding fibers by interlacing a “leotard” or “chain” and fitting.  5. Geomat according to any one of paragraphs. 1-4, characterized in that the geotextile stripes are interconnected by flashing synthetic thread with a straight or zigzag seam, while the stitch width is 2-5 mm, and the edge zones are strengthened by 1-3 cm with triple flashing.  6. Geomat according to any one of paragraphs. 1-5, characterized in that in the extended state, its length is from 8 to 15 m, the width is from 1 to 15 m, the height is from 0.05 to 0.2 m, the cell width is from 0.2 to 1.0 m.

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