RU81973U1 - PROTECTIVE FLEXIBLE COVERING OF ROCK SLOPES - Google Patents

Abstract

1. Protective flexible coating of rocky slopes, containing hinged mesh sheets woven from corrosion-resistant steel wires, hung on bearing anchors located behind the upper edge of the slope, characterized in that the coating consists of two types of steel mesh:! double torsion mesh cloths covering the slope surface and chain nets located on top of them made of galvanized steel wire rope with a ring diameter of at least 300-400 mm, with a nominal tensile strength of 16 to 50 tons! 2. The protective coating according to claim 1, characterized in that the double-torsion mesh web is fixed on the slope using mounting anchors, and across the pressure rope with a diameter of at least 12 mm. ! 3. A protective coating according to claims 1 and 2, characterized in that in the double-torsion mesh web, the wire mesh forms square or diagonal rhomboid cells, where the acute angle of the rhombus is 60 °. ! 4. A protective coating according to claims 1 and 2, characterized in that at the foot of the slope, a steel cable fixed by anchors is passed through the lower edge of the coating.

Description

The invention relates to the field of transport construction in cramped mountainous areas and is intended to stabilize deformable rocky landslides fractured slopes and can be used as protection of railways and roads, industrial facilities, settlements from geological processes, in various regions of the country, in complex climatic and geocryological conditions.

More often in construction practice, cable structures are used to protect objects from dangerous geological processes - cables, stretched in the longitudinal and transverse directions and anchored into the array, clamps securing the cables at their intersections, and pressure devices that tighten the cables. It turns out a wire rope stretched and tightly fixed on the slope, reinforcing a single surface, but not protecting the underlying ledges (Japanese Patent 2965517 Ito Kozo).

The disadvantage of this design is its low reliability and the complexity of mounting. The design does not protect the underlying horizons from falling out of pieces of rock from the upper ledges, which creates the danger of people and equipment working on them, and the process of hanging and attaching cables in areas of great length and height is laborious; A large number of cables and pushing devices on slopes are required.

Anti-landslide metal mesh is also known, consisting of intertwined vertical and horizontal wire rods arranged with different pitch. A protective wire harness is attached along the side edge of the grid parallel to the vertical rods (Japan patent No. 2717515, Е02Д 17/20 Anti-landslide metal mesh (patent holder Sanva K.K., author Hanamoto Shuneo, Japanese priority, application No. 289589)).

A disadvantage of the known design is the low reliability when reinforcing high slopes of great length.

The fastening with the help of wire strapping on the slope is a structurally weak fastening and does not allow the quick replacement of damaged mesh sections.

In addition, when the pieces of rock fall out, this grid is not able to hold them, creating the danger of the work of people and equipment located at the base of the slope.

It is also known a protective coating of cross-shaped elements to strengthen the slopes of roads, slopes, containing many cross-shaped elements made with the possibility of their formation of a frame with niches for

filling with ballast soil and fixers of their position (RF patent No. 2032022, IPC E02D 17/20).

The cross-shaped elements of this protective coating require precise manufacturing in order to securely fix during assembly, which increases labor and material costs.

The closest to the invention in technical essence and the achieved result are protective flexible designs of mounted grids (mesh sheets) covering the slope surface (slope) to prevent talus and falling rock fragments on the protected object, woven from durable corrosion-resistant steel wires (see the experience of using structures represented by Azov Kanat-Set LLC, Gorodissky & Partners Law Firm LLC (patent 229561 cl. E02D 17/20).

The disadvantages of these designs are reduced stability, low operational reliability with seismicity.

The objective of the present invention is to reduce the material consumption and labor costs for the construction of structures from a combined mesh coating to protect transport communications and objects from dangerous geological processes while ensuring the required strength, stability, durability with high seismicity in hard-to-reach mountain areas.

The proposed combined mesh construction consists of a double torsion mesh and a chain-type mesh, the use of which is especially effective in cramped conditions, when the construction of anti-rock structures is associated with the implementation of a large amount of laborious work, the mechanization of which is extremely difficult.

This design is rational for the protection of steep rocky slopes (slopes), broken by a relatively thick system of cracks, which threaten to fall on the path of a large number of rock fragments.

This type of structure is formed in such a way that, if present, in contrast to the well-known wire fences, it perceives loads from talus and large one-time dumps (more than 0.3 m ³ ), which is very important when placing protected objects, railways and highways at the foot of rocky slopes.

The problem is solved due to the fact that the protective flexible coating of rocky slopes with hinged mesh sheets woven from corrosion-resistant steel wires hung on bearing anchors located behind the upper edge of the slope, according to the invention, the coating includes two types of steel nets: double torsion mesh covering the slope surface , and on top of them, chain nets made of galvanized steel wire rope with a ring diameter of at least 300-400 mm with a nominal strength tearing from 16 to 50 tons, while the double torsion mesh web is fixed to the slope using mounting anchors, and across the clamping cable with a diameter of at least 12 mm, in the double torsion mesh wire mesh forms square or diagonal rhomboid cells, where the acute angle of the rhombus 60 °, at the foot of the slope

a steel cable fixed by anchors is passed through the lower edge of the coating, which prevents debris from entering the protected object.

The given set of features provides a technical result, expressed in reducing the cost, construction time during the construction of a durable, stable protective coating in cramped, inaccessible mountainous areas with high seismicity, observing environmental protection.

Various specific embodiments of the invention, as well as other advantages, are explained in more detail below with reference to the drawings, in which Fig. 1 shows a combined mesh structure for protecting transport communications from dangerous geological processes;

figure 2 shows two types of nets: double torsion and chain mail nets on top of them;

figure 3 shows the design of the carrier and mounting anchor;

figure 4 shows the connection of the mesh panels with a rope and anchor brackets.

Protective flexible coating of rocky slopes and the method of device 1 includes: double torsion mesh 2 fixed in an almost vertical position on a slope woven from corrosion-resistant wires, the wire is made of high strength steel having a nominal strength in the range of 980-220 N / mm ² , moreover, twisted wire was used as such steel wire, the length of the double torsion mesh web corresponds to the length of the covered slope, and the width is 3.0 m.

One of the options for attaching the mesh at the bottom of the slope, a steel cable 3 is passed along the lower edge of the mesh and every 4-5 m is secured with anchors 4 (Fig. 2).

After attaching to the supporting anchors 5, the mesh panels are lowered down the slope and securely connected along the entire length with a wire 6 having the same diameter as the wire of the mesh itself or with a cable (Fig. 1).

For a snug fit of the mesh to the slope, it is fixed with mounting anchors 7, the total length of which is at least 2.0 m (Fig. 3).

On top of the double torsion nets, a chain-link mesh 8 is hung on a supporting anchor, which is woven from separate independent rings 9 of a diameter of 350-420 mm. Each inner ring is connected along the perimeter with six adjacent rings, which are made of galvanized steel wire rope with a diameter of 3-4 mm, each ring withstands an explosive load of 22 tons, performing the functions of a "steel web" (figure 4), limit the movement of landslide-talus material in the direction of the slope, in the case of one-time large outfalls (more than 0.3 m ³ ), the grid regulates their fall and they slide along slope 10, losing some of the kinetic energy due to friction, changing shape from round to ellipsoidal, thereby reducing the energy of interaction of the rock fragment with the grid. 11 - the axis of the anchor, 12 - the rope connecting the chain mail mesh, 13 - anchor brackets connecting the panels.

Mounting of protective nets is carried out with strict adherence to the sequence of technological operations: uphill slopes 10 are carefully inspected, unstable stones and blocks are removed, cutting down

shrubs, after which they start drilling wells and sealing reinforcing rods in them, bearing anchor 5 made of reinforcing steel of class AV, 32 mm in diameter, at least 4.3 m long, on cement mortar, with cement grade not less than 400 (Fig. 3 )

The axis 11 of the supporting anchor 5 should be perpendicular to the edge of the slope, then we install the double torsion mesh 2, the rolls are delivered to the top of the slope, where they are aligned and installed on the edge of the slope, the edges of the mesh 2 are attached to the installed anchors 5, then the mesh 2 is rolled down the slope 10 and fastening the panels of the mesh 2 using wire twists or a stapler with a step of 0.2 m along the length of the canvas and securing it at the bottom of the slope 10. The double torsion mesh 2 retains small fractions of the collapse material.

Depending on the type of slope and its height, the rolls are lifted with blocks using a winch, based on the pulling force of the winch, which eliminates the problem of manually laying the roll on the top of the slope and any connection between the rolls, in addition, the rolls are rolled along slope 10 in one step.

Bearing anchors 5 are located at a distance of 15.0 m from the upper canvases of chain mail 8, which accepts the main load.

Depending on the geometric parameters and the engineering-geological description of the slope 10, the strength and geometric parameters of the bearing anchors are calculated (Fig. 3).

A strength calculation is carried out, according to the developed method, strength calculations of the combined mesh sheet 8 are carried out on the basis of the weight of the maximum possible rocky outfall with a volume of more than 3.0 m ³ , the breaking load of the shell shell ring 9.

Coefficients of overload and reliability are accepted K overload _. = 1.5 and K _rel. = 3.0.

Chain mail 9 is mounted from paintings of 3 × 10 m, which are interconnected by a rope 13 with a diameter of 12 mm and anchor brackets 14 (Fig. 4). The fastening of the chain mail mesh 8 and the double torsion mesh 2 to each supporting anchor 5 is carried out by two ropes, which are passed through all the loops of the reinforcing bars, interconnected by electric welding.

The network 8 is additionally supported on the slope by mounting anchors 7 made of hot-rolled rod reinforcement 32 mm in diameter, reinforcement class AV, embedment depth 1.80 m, on the section from the edge of the slope edge to the top of the mesh 9 webs, mounting anchors 7 3.0 m long are installed, 2.80 m depth.

The invention allows:

- ensure the safety of traffic for many years, when using the above structures is not violated and is not limited to traffic;

- reduce environmental damage (over time, grass and shrubs that hide the mesh (aesthetics) grow through protective mesh 9), but also provide additional adhesion to the surface of slope 10, limiting the possibility of rockfall, increasing traffic safety on railways and highways and national economic facilities values at the bottom of the slope.

Claims (4)

1. A protective flexible coating of rocky slopes, containing hinged mesh sheets woven from corrosion-resistant steel wires, hung on bearing anchors located behind the upper edge of the slope, characterized in that the coating consists of two types of steel mesh: double torsion mesh cloths covering the slope surface and chain nets located on top of them made of galvanized steel wire rope with a ring diameter of at least 300-400 mm, with a nominal tensile strength of 16 to 50 tons. 2. The protective coating according to claim 1, characterized in that the double-torsion mesh web is fixed on the slope using mounting anchors, and across the pressure rope with a diameter of at least 12 mm. 3. A protective coating according to claims 1 and 2, characterized in that in the double-torsion mesh web, the wire mesh forms square or diagonal rhomboid cells, where the acute angle of the rhombus is 60 °. 4. A protective coating according to claims 1 and 2, characterized in that at the foot of the slope, a steel cable fixed by anchors is passed through the lower edge of the coating.