RU124697U1 - THREE-DIMENSION GEO-CELL AND GEO-CELL TENSION DEVICE - Google Patents

Abstract

1. Three-dimensional geocell containing ribbons made of synthetic polymeric material with filtering ability, which are interconnected by fastening seams, equal to the material of the ribbons, with their planes forming in the plan of rectangular cells and have loops or cords for temporary fastening to the tensioning device tapes at the time of filling the cells, characterized in that as a synthetic polymer material contains polyester fabric impregnated with an antiseptic, with the formation in terms of cells square shape, and the tapes are made with bending of the upper part and the formation of a cavity for the free movement of the cable from a synthetic material, comparable in strength with the strength of the material of the tapes; one end of which is equipped with a fixing element in the form of a hook or carbine or hook mechanism for interacting with its corresponding mount on the device for tensioning the belts, and the second end of the cable is designed for refueling in the tension mechanism. 2. A three-dimensional geocell according to claim 1, characterized in that it is additionally provided with a bottom fastened to the ribbons forming it and having an inlet for connecting to an adjacent geocell. A three-dimensional geocell according to any one of claims 1 and 2, characterized in that, in addition, inside at least a part of the cells contains a spatial reinforcing mesh of at least two reinforcing tapes with a width of 1 cm to 5 cm from polyester fabric, the opposite ends of which placed on the opposite sides of the cell so that the plane of the reinforcing tape is parallel to the plane of the tape of the polyester fabric forming the cells, or fixed in the seams, forming

Description

The proposed utility model relates to the field of increasing the bearing capacity of bases for objects located on it, namely, to means of increasing the bearing capacity of a soil base, or subgrade in water-saturated or waterlogged soils. The geocell can be used to protect slopes of roads, hydraulic structures from erosion, and also to reinforce the soil foundations of roads, airfields and other geotechnical objects.

Known geomat honeycomb structure made of flexible strips mounted on the ribs and interconnected by linear seams located in a checkerboard pattern. The strips are made of non-woven geotextiles, hardened by sizing and stitched seams located uniformly over the area of the strips and parallel to their base. The distance between the seams and the width of the stitch are 2-5 mm, and the connection of the strips between themselves is made by one or more stitched seams with reinforcement of the edge zones (RU No. 2180030 C1, E02D 17/20).

However, the absence of a bottom, as an integral element of the design of the geomat, does not allow guaranteed to keep loose bulk material in its cells, the location of the seams in a checkerboard pattern leads to different stresses in the strips forming its structure when the geomat is stretched, which negatively affects the preservation of the shape of the cell, its stability when filling with bulk material. This leads to the appearance of uneven areas with different bearing capacity and, as a result, to undesirable local subsidence.

Known geomat formed by tapes of non-woven synthetic material, stacked parallel to each other with the formation in the transverse direction of the foot and connected in adjacent tapes with each other along their height by welded solid seams with alternating along the length of the tape connecting two tape seams in a staggered manner with seams connecting these tapes with adjacent outer tapes in such a way that when moving the tapes in the direction of the longitudinal axis of the geomat, perpendicular to the initial moment of their surface, they form a rhombus prominent cell, wherein at least part of the strips is formed with reinforcing elements (RU №60545 U1, E02D 17/12, 2006 YG).

However, the diamond-shaped structure and the staggered order of the joint seams do not provide adequate stability of the tapes when filling diamond-shaped cells with bulk material, which leads to different densities of the geomat's area and, as a result, different bearing capacity. The lack of a bottom, as an integral element of the design of the geomat, does not allow guaranteed to keep loose bulk material in its cells.

Known geogrid containing a set of flexible tapes stitched 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 the ground and applying transverse and longitudinal calculated tensile forces to the extreme tapes followed by fixing on the soil of the cells around the perimeter of the stretched set of flexible tapes, in which to increase stability, strength and lateral gesture flexible bones of the geogrid are made of soft rolled materials, and the cells of the geogrid are hexagonal, for which the bonding 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 (RU No. 2228479 C1 , F16L 1/00, 2004).

The shape of the cell in the form of a hexagon does not provide the necessary uniformity of voltage forming the cell tapes, which also leads to the disadvantages described above. In addition, the lack of a bottom does not guarantee the reliability of the structure created using this geogrid due to the filtration and leaching of bulk material from its cells.

Known cellular design of the geomatrix, containing a set of flexible tapes fastened perpendicular to their long sides and staggered seams with the possibility of forming a cellular structure filled with bulk soil, which is equipped with a base made of a filtering non-woven synthetic material that is fastened with a cellular structure. The flexible ribbons forming the cellular structure are made of soft rolled materials (Application No. 2005126259, E01C 13/00, 2007).

However, the staggered arrangement of the fastening tapes of the seams leads to the appearance of multidirectional force vectors and does not provide the required reliability of the joint under tension within the elastic deformation of the flexible tapes forming the cellular structure, which negatively affects the stability of their position when loading material into the cells and does not provide the necessary uniformity bearing capacity of a cellular structure filled with bulk soil. The use of soft rolled materials for the structure of the cell will also not ensure the stability of its shape when filling with bulk material and will lead to a non-uniform load-bearing capacity of the geomatrix

Known geobox (prototype) containing tapes, at least some of which are made of synthetic polymeric material with filtering ability. The tapes are made at least two-layer and interconnected by a sewing seam with the formation of their planes in terms of cells of a rectangular shape. The tapes have loops or cords for temporary fastening to the device for tensioning the tapes at the time of filling the cells, which are sewn to at least one vertex of the cell.

A device is known for tensioning geobox tapes made in the form of beams connected to form a rectangle in terms of beams and rods mounted on beams in parallel with each other for connecting with cells located parallel to one of the diagonals of a rectangle formed by beams. (Pat. No. 114689 RU)

The disadvantages of the prototype is the implementation of the two-layer tapes, which greatly complicates the design, causes a shift in the center of gravity in the loaded cells. The resulting dynamic stress contributes to the violation of the reliability of the design, additional load on the device for tensioning the tapes. The fastening of tapes in the form of a loop does not provide sufficient tension of the upper part of the cells at the time of filling it with soil, as a result of which the walls of the cells become curved and sag, which leads to incomplete filling of the structure with filling soil or to its overuse.

The technical problem solved by the claimed utility model is the creation of a geocell, which provides a uniform density distribution of the material loaded into the cells while ensuring the stability of the cell walls due to the creation of longitudinal tapes of their stressed state when loading, guaranteed to keep various bulk material loaded into the cells under the calculated load, including the number of soil, preventing its leaching in various hydrogeological operating conditions. Increasing the life of the geocell.

This is achieved by the fact that in a three-dimensional geocell, containing tapes made of synthetic polymeric material with filtering ability, which are interconnected by fastening seams, equal to the material of the tapes, with their formation by planes in the plan of rectangular cells and have loops or cords for temporary fastening to the device for tensioning the tapes at the time of filling the cells, as a synthetic polymer material contains a polyester fabric impregnated with an antiseptic with the formation in plan of the cell a square shape. The tapes are made with a bend of the upper part to accommodate a cable made of synthetic material, comparable in strength with the strength of the material of the tapes. One end of the cable is equipped with a locking element in the form of a hook or carbine or hook mechanism for mounting it on a device for tensioning tapes. The second end of the cable is designed for refueling in the tension mechanism. Additionally, at least a part of the cells may have a spatial reinforcing mesh of at least two reinforcing tapes with a width of 1 cm to 5 cm made of polyester fabric, the opposite ends of which are placed on opposite sides of the cell so that the plane of the reinforcing tape is parallel the planes of the tape made of polyester fabric forming the cells or are fixed in the seams forming the corners of the cell, with each subsequent reinforcing tape located above the previous one. The geocell can be additionally provided with a bottom fastened to the ribbons forming it and having an inlet for connection with an adjacent geocell.

The device for tensioning the geocell tapes, made in the form of beams connected to form a rectangular mounting frame and installed on the beams parallel to one of the diagonals of the boom rectangle for connecting to the cells, is additionally equipped with a tensioning mechanism for refueling the cable located in the fold of the polyester fabric tape and with a mount for interaction with the locking element of the opposite end of the cable. mounted on the beams of one of the sides of the mounting frame corresponding to each of the ends of the cable.

Figure 1 shows a three-dimensional geocell cell with a reinforcing mesh of two tapes, the opposite ends of which are placed on opposite sides of the cell

Figure 2 presents the cell geocell three-dimensional with a reinforcing mesh of four tapes, the opposite ends of which are placed on opposite sides of the cell.

Figure 3 presents the cell geocell three-dimensional with a reinforcing mesh of eight tapes, the opposite ends of which are placed on opposite sides of the cell.

Figure 4 presents the cell geocell three-dimensional with a reinforcing mesh of two tapes, the opposite ends of which are placed in opposite corners of the cell

Figure 5 presents the cell geocell three-dimensional with a reinforcing mesh of four tapes, the opposite ends of which are placed in opposite corners of the cell

Figure 6 presents a device for tensioning the geocell tape three-dimensional

The three-dimensional geocell contains installed on the end of the tape 1 of a polyester fabric. Tapes 1 are interconnected with the formation of their planes in terms of square cells. Inside the cell are attached to the tapes 1 with a textile seam or a welded seam or a seam identical in strength, reinforcing tapes 2, which improves the stability of the cells when they are backfilled. The seam is laid across the width of the reinforcing tape 2 parallel to the height of the cell in the plane of the tape 1 (Fig. 1, 2, 3) or in the corners of the cell (Fig. 4, 5). To prevent distortion of the cell walls, the number of reinforcing tapes should be even. The upper edge of the tape 1 is made with a hem 3 for free movement of the synthetic cable 5, which, together with loops or cords 4 for ties, serves for temporary fastening to the device for tensioning the ribbons at the time of filling the cells. The device for tensioning the geocell tapes is made in the form of a rectangular mounting frame of beams 6. On the beams 6 are installed parallel to one of the diagonals of the rectangle of the rod 7 for connection with the cells. On the beam 6 of one of the sides of the mounting frame, a tensioning mechanism 8 is installed for refueling the cable 5. For the fixing element 10 (for example, the locking hook) of the opposite end of the cable 5, the fasteners 9 (for example, fixing rings) are installed on the beams 6 for interaction with the fixing element 10 After filling the cell with soil, the cable 5 is removed or its tension is removed. The attached banner in the form of a bottom is made with an overflow (at the outer part of the height of the geocell along its perimeter), at least on its two sides.

The use of polyester fabric as the material of the ribbons forming the cells makes it possible to provide a high filtering ability of the cell and to prevent leaching of the loose soil, due to the uniformity of the arrangement of small-sized pores of the fabric. The simultaneous use of a mesh of reinforcing tapes and a tension cable allows you to maintain the design position of the cells by stabilizing the position of the tapes when loading, provides a uniform density surface of the soil to be filled over the cell area. The implementation of the cell with the base in the form of a square eliminates the dynamic stress arising as a result of uneven tension in the walls of rectangular cells. Impregnation of polyester fabric with an antiseptic increases the service life of the geocell, as reduces the likelihood of fungal formations during its operation, storage and storage.

Claims (4)

1. Three-dimensional geocell containing ribbons made of synthetic polymeric material with filtering ability, which are interconnected by fastening seams, equal to the material of the ribbons, with their planes forming in the plan of rectangular cells and have loops or cords for temporary fastening to the tensioning device tapes at the time of filling the cells, characterized in that as a synthetic polymer material contains polyester fabric impregnated with an antiseptic, with the formation in terms of cells square shape, and the tapes are made with bending of the upper part and the formation of a cavity for the free movement of the cable from a synthetic material, comparable in strength with the strength of the material of the tapes; one end of which is equipped with a locking element in the form of a hook or carbine or hook mechanism for interacting with its corresponding mount on the device for tensioning the tapes, and the second end of the cable is designed for refueling in the tension mechanism. 2. The three-dimensional geocell according to claim 1, characterized in that it is additionally provided with a bottom fastened to the ribbons forming it and having an inlet for connecting to an adjacent geocell. 3. A three-dimensional geo-cell according to any one of claims 1 and 2, characterized in that, additionally, inside at least part of the cells contains a spatial reinforcing mesh of at least two reinforcing tapes with a width of 1 cm to 5 cm from polyester fabric, opposite the ends of which are placed on the opposite sides of the cell so that the plane of the reinforcing tape is parallel to the plane of the tape made of polyester fabric forming the cell, or fixed to the seams forming the corners of the cell, with each subsequent reinforcing tape located above the previous one. 4. The device for tensioning the geocell three-dimensional tapes, made in the form of beams connected to form a rectangular mounting frame and installed on the beams parallel to one of the diagonals of the boom rectangle for connecting to the cells, characterized in that it is additionally equipped with a tensioning mechanism for refueling the cable located in the bend of the tape made of polyester fabric, and a mount for engaging with a fixing element of the opposite end of the cable mounted on beams of one of the sides of the mounting frame corresponding to each end of the cable.

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