RU57300U1 - DESIGN OF ATTACHMENT OF GROUND SLOPE - Google Patents

Abstract

The utility model relates to the field of construction, namely, to reinforce slopes during the construction of roads and other embankments (dams, drilling sites, etc.), in order to prevent their destruction under the influence of atmospheric influences. The technical result achieved is to reduce the material consumption of the structure by maximizing the tensile strength of the flax of the spatial reinforcing cage, as well as increasing the reliability of the structure. The design of the fastening of the soil slope contains a spatial reinforcing frame of polymer tapes fixed on the slope with anchors installed on the ends and interconnected to form cells in which the filling material is placed. The frame consists of longitudinal and transverse relative to the slope forming polymer ribbons forming quadrangular, mainly rectangular cells. The longitudinal and transverse tapes have slots located along the length of the tapes with the same pitch between the centers of the slots and made perpendicular to the long end of the tape, while the step between the centers of the slots in the longitudinal tapes is equal to or different from the step between the centers of the slots in the transverse tapes. The longitudinal tapes are placed with the slots pointing upwards, into which the transverse tapes are inserted, with the slots facing down, with the ends of each slot of both longitudinal and transverse tapes being connected together.

Description

The utility model relates to the field of construction, namely, to reinforce slopes during the construction of roads and other embankments (dams, drilling sites, etc.), in order to prevent their destruction under the influence of atmospheric influences.

Closest to the claimed utility model in technical essence is a device for securing the slope of an earth structure, mainly on a frozen base, containing obliquely mounted on the slope and fixed by anchors geogrids (spatial frames), diamond-shaped during tension, the cells of which are formed interconnected, preferably perforated, polymer tapes, at least in part of the cells placed filling material, preferably bulk, with the lower edge placed on the slope of the geogrid is adjacent to its section, located preferably in a horizontal plane, the cells of which are filled with and / or peat-sand mixture, and / or sand and / or crushed stone, preferably a fraction of 20-40 mm, and in the area of flooding with crushed stone and / or concrete, on the slope of the geogrid stacked with mutual overlapping of their lateral edges by an amount not more than half the width of the cell, and interconnected (RF Patent for utility model No. 34945, priority 2003.12.20).

The main disadvantage of the known technical solution is the impossibility of orienting the tapes that make up the spatial frame, relative to the action of the maximum loads on the dirt slope, in connection with which there is an overestimated material consumption of the frame. The position of the tapes in the spatial frame causes uncertainty in their stress-strain state, not the use of strength

properties of the tapes themselves, which experience mainly bending loads, and the seams - tensile loads (across the seam). In addition, in the manufacture of a spatial framework, it is necessary to use tape welding, which requires expensive equipment and ensuring the equal strength of all welds. During the operation of the spatial frame on a dirt slope in the weld seam of the frame, significant loads can occur, aimed at breaking the seam, which can lead to destruction of the seam and the entire frame as a whole.

When creating this useful model, the technical problem was solved to reduce the material consumption of the structure by maximizing the tensile strength of the flax of the spatial reinforcing cage, as well as increasing the reliability of the structure.

In addition, when the proposed design is used, the fundamental principle of reinforcing building structures is used, namely, the placement of reinforcing products in the structure, taking into account the direction of action of maximum stresses.

The stated technical problem is solved in that the construction of the soil slope fastening comprises a spatial reinforcing frame fixed on the slope with anchors from polymer tapes mounted on the ends and interconnected to form cells in which the filling material is placed, according to a useful model, the spatial reinforcing frame consists of longitudinal and transverse relative to the slope of the polymer tapes forming quadrangular, mainly rectangular cells, and spatial reinforcement scaffold installed directly on the ground or slope, or to the separation layer, laid on the ground slope.

The separation layer may be made of geosynthetics, or fiberglass, or non-woven material.

The cells of the spatial framework can be filled with and / or peat-sand mixture, and / or sand, and / or crushed stone, preferably fractions of 20-40 mm, and in the flooding zone with crushed stone and / or concrete.

The longitudinal tapes of the spatial reinforcing cage have slots located along the length of the longitudinal tape with the same pitch L _np between the centers of the slots and made perpendicular to the long end of the longitudinal tape. The transverse tapes have slots located along the length of the transverse tape with the same pitch L _nn between the centers of the slots and made perpendicular to the long end of the transverse tape. The step L _np between the centers of the slots in the longitudinal tapes is equal to or different from the step L _nn between the centers of the slots in the transverse tapes. The longitudinal tapes are placed with the slots pointing upwards, into which the transverse tapes are inserted, with the slots facing down, with the ends of each slot of both longitudinal and transverse tapes being connected together.

The depth of each slot in the longitudinal and transverse tapes of the spatial frame is equal to half the width of the tape b _l ± 5%, and the width of each slot is not less than the thickness of the tape t _l . The value of the depth of the slot in the tapes is determined by the fact that in the spatial frame, which is assembled from these tapes, the ends of the longitudinal and transverse tapes would lie in two parallel planes.

The distance from the extreme slots to the short end of the tape lies in the range from 0.2 m to 1.0 m. This distance should ensure the connection of the tapes when building spatial frames.

In the sections of tapes between the extreme slots and the short ends of the tapes, holes can be made for mounting fasteners when building tapes (assembling adjacent frames), and longitudinal and transverse tapes can be made with or without drainage holes.

The essence of the utility model is illustrated by drawings, where: in Fig.1 shows a cross section of the structure of the fastening of the soil slope; figure 2 is a front view of the mounting structure of the soil slope; figure 3 is a top view of the junction of the longitudinal and transverse tapes of the spatial frame, figure 4 is a view aa in figure 3, figure 5 is a view bb in figure 3.

The design of the fastening of the soil slope includes a spatial reinforcing cage, consisting of longitudinal 1 and transverse 2 relative to the slope forming polymer tapes forming quadrangular, mainly rectangular cells. The spatial reinforcing cage is installed either directly on the slope soil 3, or on the separation layer 4 laid on the slope soil. The separation layer can be made either from geosynthetics, or from a fiberglass mesh, or from non-woven material.

The spatial reinforcement cage is fixed on the dirt slope with anchors 5.

The spatial reinforcement cage is installed from the lower edge of the dirt slope to the pavement 6.

The longitudinal tapes 1 of the spatial reinforcing cage have slots (not shown conditionally), located along the length of the longitudinal tape with the same step L _np between the centers of the slots and made perpendicular to the long end of the longitudinal tape. The transverse tapes 2 have slots (not shown conventionally) located along the length of the transverse tape with the same pitch L _nn between the centers of the slots and made perpendicular to the long end of the transverse tape. The step L _np between the centers of the slots in the longitudinal tapes is equal to or different from the step L _nn between the centers of the slots in the transverse tapes.

The depth of each slot in the longitudinal and transverse tapes of the spatial frame is equal to half the width of the tape b _l ± 5%, and the width of each slot is not less than the thickness of the tape t _l .

The longitudinal tapes 1 are placed with the slots pointing upwards, into which the transverse tapes 2 are inserted, with the slots facing down, with the ends of each slot of both the longitudinal and transverse tapes being connected together. The bonds can be made of polymer strips 7 and 8 attached to ribbons at their ends, for example, with staples using staples. In this case, the strips 7 connecting the longitudinal tapes are placed in the recesses 9 made in the transverse tapes 2, and the strips 8 connecting the transverse tapes are placed in the recesses 10 made in the longitudinal tapes 1.

In the sections of tapes between the extreme slots and the short ends of the tapes, holes can be made (not shown conditionally) for mounting fasteners when building tapes (assembling adjacent frames)

Tapes can be made both with drainage holes and without them. The distance from the extreme slots to the short end of the tape lies in the range from 0.2 m to 1.0 m.

There are two ways to connect spatial frames to each other. According to the first method, spatial frames are interconnected by combining with the overlap of longitudinal (transverse) tapes of adjacent frames and connecting the tapes with metal staples using staplers.

According to the second method, spatial frames are interconnected by combining holes made in the sections of tapes between the extreme slots and the short ends of the tapes (not shown conventionally) longitudinal (transverse) tapes of adjacent frames and the passage of fasteners into them, which can serve as steel strips or strips of polymer material, which should be equipped with clamps for the position of the combined tapes.

When reinforcing soil slopes in order to prevent their destruction under the influence of atmospheric influences, elevated loads perceive tapes located perpendicular to the axis of the road

(transverse tapes), as a result of which the distance between them should be less than the distance between the longitudinal tapes.

In the proposed construction of the fastening of the soil slope, the fundamental principle of reinforcing building structures is used, namely, the placement of reinforcing products in the structure, taking into account the direction of maximum stresses, which makes the operation of structures more reliable.

Claims (4)

1. The design of the fastening of the soil slope, containing a spatial reinforcing frame fixed on the slope with anchors from polymer tapes mounted on the ends and interconnected to form cells in which the filling material is located, characterized in that the spatial reinforcing frame is installed or directly on the soil slope, or on the dividing layer, laid on a dirt slope, and consists of longitudinal and transverse relative to the slope forming polymer ribbons forming a quadrangle second, mainly rectangular cells, longitudinal tapes have slots located along the length of the longitudinal tape with the same pitch L _np between the centers of the slots and made perpendicular to the long end of the longitudinal tape, transverse tapes have slots located along the length of the transverse tape with the same pitch L _nn between the centers of the slots and formed perpendicular to the long transverse end bands, wherein the step L _np between the centers of longitudinal slots in the strips is equal to or different from the pitch L _nn between centers of slits in the transverse tape Longitudinal ribbons slits arranged upwardly, in which are inserted respectively transverse cuts down belt, the ends of each slot of both longitudinal and transverse strips are interconnected links. 2. The design of the fastening of the soil slope according to claim 1, characterized in that the depth of each slot in the tapes making up the spatial frame is equal to half the width of the tape b _l ± 5%, and the width of each slot is not less than the thickness of the tape t _l , in areas tapes between the extreme slots and the short ends of the tapes can be made holes for mounting fasteners when assembling adjacent frames, while the tapes of the spatial frame can be made with or without drainage holes, and the distance from the extreme slots to short th end of the tape lies in the range from 0.2 m to 1.0 m. 3. The construction of the soil slope attachment according to claim 1, characterized in that the separation layer is made of and / or geosynthetics and / or fiberglass and / or non-woven material. 4. The construction of the soil slope attachment according to claim 1, characterized in that the cells of the spatial framework can be filled with and / or peat-sand mixture and / or sand and / or crushed stone, preferably fractions of 20-40 mm, and in the flooding zone crushed stone and / or concrete.