RU2618694C1 - Method of erecting combined retaining wall - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: erecting the combined retaining wall from the cylinders is carried out gradually; for this purpose, at first a combined flexible apron is laid in the base. On the combined flexible apron formed in this way, moulds are installed, which have the form of hollow cylinders. From the top, stone is filled into the filling opening of the mould, after which the mould is gradually removed as it is filled. The diameter of cylindrical gabions is 0.5÷1.0 m. One side of the retaining wall, which works by compression, is concreted. The thickness of the protective concrete coating is 0.1÷0.3 m. Vertical expansion joints are arranged in the protective cladding of the mesh frame. The space between the cylinders in the docking areas is filled with concrete, which provides the increased strength of adhesion of cylindrical gabions together. The other side of the combined retaining wall, which works by stretching, is reinforced with a woven or other mesh. Inside the cylindrical gabions there are mesh bridges vertically oriented along the action direction of the bending moments.

EFFECT: increasing the carrying capacity during the operation by bending and shear and protecting the retaining wall against abrasion by deposits; the proposed combined retaining wall is cheaper and more reliable in the operation than the known analogous technical solutions; the efficiency of these structures is 1,5-2 times higher, since the structure is capable of operating by bending loads.

5 cl, 3 dwg

Description

The invention relates to hydraulic engineering and can be used as a device for strengthening slopes, shore protection structures in eroded riverbeds, canals and other structures.

Known gabion retaining wall, including stones and mesh [1]. The disadvantages of this technical solution are:

- the gabion net can be subjected to strong abrasion by sediment during operation;

- bearing capacity for bending and shear of such a structure is quite low;

- the design and method of construction is quite complicated;

- as such, the technical solution is inefficient to use for fastening high slopes.

The closest technical solution is the method of construction of a combined retaining wall, including stones and a grid with hexagonal cells [2]. The disadvantages of this technical solution are:

- the relative complexity of the design of the gabion retaining wall;

- bearing capacity for bending and shear of such a structure is quite low;

- economically, it is not a favorable technical solution.

The purpose of the invention is to increase the bearing capacity when working on bending and shear and to protect the retaining wall from abrasion by sediment.

This goal is achieved in that the combined retaining wall consists of cylinders with a vertical orientation. A combined retaining wall is constructed from the cylinders, gradually for this purpose, first, a combined flexible “apron” is laid in the base. On the combined flexible “apron” formed in this way, hollow-cylinder shapes are installed.

From above, a stone is filled into the loading hole of the form, after which the form is gradually removed as it is filled. The diameter of cylindrical gabions is 0.5–4.0 m (Figs. 2, 3).

From the results of experimental studies of prismatic and cylindrical gabions, the elastic modulus of prismatic and cylindrical gabions, respectively [3]

;

.

;

.

Then

σ _pr = E _pr ⋅ε; σ _c = E _c ⋅ε,

where ε are the relative deformations of prismatic and cylindrical gabions, respectively.

Absolute deformations of prismatic and cylindrical gabions will be

,

,

where E _i, F -, respectively, elastic modulus and cross-sectional area of the gabion; L is the length of the gabion. According to the developed method, knowing the elastic moduli of prismatic and cylindrical gabions, we can calculate the possible deformations from compressive loads N.

One side of the retaining wall, which works in compression, is concreted. It is known that the compressive strength of concrete is tens of times greater than tensile, and this will significantly enhance the bearing capacity of the structure during bending. The thickness of the concrete layer depends on the magnitude of the calculated bending moment. Concrete is also a reliable wall protection against abrasion by sediment. The thickness of the protective concrete coating is 0.1 ÷ 0.3 m. The protective lining of the mesh frame is broken by vertical expansion joints. The space between the cylinders at the joints is filled with concrete, which provides increased adhesion to the cylindrical gabions between themselves.

The other side of the combined retaining wall, which works in tension, is reinforced with a wicker or other mesh. It is known that iron has a large tensile strength. The thickness of the wire mesh depends on the magnitude of the calculated bending moment.

To strengthen the bearing capacity when working on bending loads, as well as the stability of the structure to capsize, the wall has a stepped cross-sectional shape with decreasing step widths to the top (Fig. 1).

Significantly increases the bearing capacity for bending loads and the stability of the combined retaining wall, the presence of a flexible combined "apron" (Fig. 1). The presence of a flexible “apron” enhances the shear and tipping stability of the structure, and the specific loads on the foundation soil are significantly reduced.

Inside the cylindrical gabions there are mesh jumpers vertically oriented along the direction of action of the bending moments, enhancing stability on the action of bending loads. As a mesh, a double or twisted braided or hexagonal mesh can be used.

In FIG. 1 shows a combined retaining wall, general view; in FIG. 2 - shows a combined retaining wall, top view; in FIG. 3 - a cylindrical gabion frame made of a grid with hexagonal cells filled with stone, axonometry.

The combined retaining wall 1 props the embankment 2 and protects the banks 3 from erosion by the flow of water. The combined retaining wall 1 consists of a mesh frame 4, in which the stone 5 is laid. At the joints 6, the mesh frames 4 are interconnected. To protect the base of the combined retaining stack 1, a flexible “apron” 7 is provided. To protect the mesh from abrasion by sediment, a protective lining is provided 8. On the side of the combined retaining wall 1 with soil, a metal mesh 9 and anti-suffusion material 10 are provided. Inside the mesh frame 4 there are mesh jumpers 11. On the protective coating 8 of the flexible “apron” 7 structural seams are provided 12. The protective lining 8 of the mesh frame 4 is broken by vertical expansion joints 13. The space between the cylinders at the joints is filled with concrete 14.

The method of construction of a combined retaining wall is as follows. A combined retaining wall 1 of the cylinders with a vertical orientation is constructed, gradually for this purpose, first, a combined flexible “apron” 7 is laid at the base. Forms having the form of hollow cylinders are formed on the combined flexible “apron” 7 formed in this way.

From above, a stone 5 is filled into the loading hole of the mold, after which the mold is gradually removed as it is filled. The diameter of cylindrical gabions is 0.5 ÷ 1.0 m (Figs. 2, 3). In the places of the docking 6 mesh frames 4 are interconnected by a wire.

One side of the retaining wall, which is in contact with water 3 and works for compression, is covered with a protective cladding 8 of concrete. It is known that the compressive strength of concrete is tens of times greater than tensile, and this will significantly enhance the bearing capacity of the structure during bending. The thickness of the layer of the protective lining 8 depends on the magnitude of the estimated bending moment. Concrete is also a reliable wall protection against abrasion by sediment. The thickness of the protective coating 8 is 0.1–0.3 m. The protective lining 8 of the mesh frame 4 is broken by vertical expansion joints 13. The space between the cylinders at the joints is filled with concrete 14, which provides increased adhesion between the cylindrical gabions to each other.

The other side of the combined retaining wall 1, which is in contact with the embankment 2, works in tension, reinforced with mesh 9. Iron is known to have a high tensile strength. The thickness of the wire mesh 9 depends on the magnitude of the calculated bending moment.

To enhance the bearing capacity when working on bending loads, as well as the stability of the structure on tipping, the combined retaining wall 1 has a stepped cross-sectional shape with decreasing width of the steps to the top (Fig. 1).

Significantly increases the bearing capacity for bending loads and the stability of the combined retaining wall 1, the presence of a flexible combined "apron" 7 (Fig. 1). The presence of a flexible "apron" 7 enhances the stability of the structure for shear and tipping, significantly reduces the specific load on the soil base. On the protective coating 8 of the flexible “apron” 7, structural seams 12 are provided that provide upsetting during washing.

Inside the mesh frame 4 there are mesh lintels 11, vertically oriented along the direction of action of the bending moments, enhancing stability on the action of bending loads. As a mesh, a double or twisted braided or hexagonal mesh can be used.

The proposed combined retaining wall is cheaper and more reliable in the work of well-known similar technical solutions. At the same time, the cost-effectiveness of these structures is 1.5-2 times greater, since the design is able to work on bending loads.

Information sources

1. Patent of the Russian Federation No. 2249071, IPC EB02 3/06. Gabion retaining wall / Z.G. Lamerdonov (RU); OH. Dyshekov (RU); M.M. Shakhurzov (RU); T.Yu. Khashirova (RU); R.A. Shogenov (RU); B.Z. Kambotov (RU); declared 11/18/2002; publ. 03/27/2005 (analog).

2. Patent of the Russian Federation №2249650, MKI Е02В 3/06, 3/12. Combined retaining wall / Lamerdonov Z.G., Dyshekov A.Kh., Shakhmurzov M.M., Khashirova T.Yu., Shogenov R.A., Kambotov V.Z; declared 11/18/2002; publ. 04/10/2005, Bull. No. 10. - 7 p. (prototype).

3. Lamerdonov, Z. G. Experimental studies of cylindrical gabions for the protection and protection of land from water erosion / Z.G. Lamerdonov, K.N. Duzhak // Environmental Engineering. - 2012. - No. 2.

Claims (5)

1. The method of erection of a combined retaining wall, including gabions, characterized in that the gabions are erected in the form of cylinders with a vertical orientation, the space between the cylinders at the joints is filled with concrete, the wall on the water-contacting side is covered with a protective concrete lining with vertical expansion joints, in front of which a flexible combined apron is arranged, and from the backfill side, the wall is reinforced with a metal mesh. 2. The method according to claim 1, characterized in that inside the cylindrical gabions make net jumpers vertically oriented along the direction of action of the bending moments. 3. The method according to claim 1, characterized in that the thickness of the concrete coating is 0.1 ÷ 0.3 m. 4. The method according to claim 1, characterized in that as a mesh using a braided or hexagonal mesh with double torsion. 5. The method according to claim 1, characterized in that the diameter of the cylindrical gabions is 0.5 ÷ 1.0 m

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