RU174847U1 - Mesh panel for protective anti-landslide structure - Google Patents

Abstract

The utility model relates to the field of construction equipment and can be used to strengthen mountain slopes to protect against landslides and avalanches. The purpose of the utility model is to expand the functionality of anti-landslide panels with the efficiency of absorbing the kinetic energy of falling stones and snow avalanches on a mountain slope when securing the slope. The technical task is to create a universal mesh panel for a protective anti-landslide structure with the possibility of further installation, depending on the layout of the panels on the slope with a long trapezoid base up or down, at an angle to the surface of the slope with the formation in terms of a straight line of construction or a concave / curved arc, with a vertical the position of the plane of the mounted panels or their inclination relative to the slope. The goal is achieved, and the technical problem is solved in that the mesh panel for the protective anti-landslide structure is a rigid frame with a main mesh fixed to it and an additional finer mesh, the mesh panel frame being a supporting steel frame, made in the form of a trapezoid and equipped with fixing elements symmetrically located relative to the horizontal and vertical axis of the panel, in order to be able to connect the panels together in a row, while the main grid is made ene of intersecting reinforcing rods, and an additional fine mesh grid is a double torsion wire, coupled with the mesh layer geotextile co-fastened to tensioned on a support frame supporting a steel cable, placed on the panel perimeter. In this case, the main mesh can be made in the form of a reinforcing mesh or mesh from a cable with a large cell. In this case, the additional mesh can be made flexible and can be a layer of geotextile or geotextile in combination with a flexible steel mesh.

Description

The technical solution of the mesh panel, claimed as a utility model, relates to the field of construction equipment and can be used to strengthen mountain slopes to protect against landslides and avalanches.

Known protective cover mesh structures according to the patent of Russia for utility model No. 116514 dated 05/26/2011, IPC: E02D 17/20, published on 05.27.2012, which contain hinged mesh sheets woven from corrosion-resistant steel wires hung on bearing anchors located behind the upper edge of the slope, and the combined flexible coating consists of two types of steel nets: double-torsion mesh cloths and chain-link webs made of galvanized steel wire rope are hung on top of them The functions of the steel web. The connection of the mesh cloths on the slope is carried out by ropes, anchor brackets or ropes with anchor brackets, and the fastening of the cover mesh cloths to the slope is carried out by anchors from rod reinforcement or from rod reinforcement of the screw profile. If necessary, the anchors from the rod reinforcement of the screw profile can be extended due to couplings providing tensile strength.

Thus, protective cover mesh constructions according to utility model patent No. 116514 were designed to protect against rock and rock phenomena of transport, hydraulic, industrial facilities, resort areas, new and operated railways and highways, and other communications primarily in difficult climatic and geocryological conditions, regardless of the height and steepness of the slope.

General technological features related to this analogue with the claimed technical solution consist in the use of soil anchors for fastening mesh structures on mountain slopes, as well as double torsion mesh paintings.

The main difference between this analogue and the claimed solution is that the nets are used in the analogue, and in the claimed technical solution the nets are designed as separate sections (panels) with rigid frames, as a result of which they can be mounted at an angle to the surface of the slope, as well as tiers with the formation of terraces , which significantly improves the stability of the slope, and in the case of rock-landslide phenomena, zones of debris retention appear without their acceleration and descent.

The disadvantage of the analogue is that in the prototype a two-layer chain mail mesh is fixed outside the fixed slope, and therefore, to protect extended slopes, a significant amount of installation work is required, which cannot always be performed technically at significant elevations. In addition, the construction of the analogue cannot prevent the fall of rock fragments and the avalanches from the overlying slopes, but only keeps them on the slope and prevents acceleration. It can also be noted that the protection device for this analogue is extremely difficult in the presence of large boulders, trees and shrubs on the slope.

Unlike the analogue of Utility Model Patent No. 116514, the inventive mesh panel can be mounted on a protected slope with the ability to connect the panels to each other in a row, forming a straight line in a plan or a concave / curved arc, and due to the trapezoidal configuration of the panel with the possibility of achieving a vertical position the plane of a row of panels or their inclination relative to the slope. In the claimed technical solution, in its application, metal mesh panels with a rigid frame are mounted at an angle to the surface of the slope, while extinguishing the kinetic energy of the rolling rock fragments and the dynamic effect of avalanche flows, regardless of the height and steepness of the overlying hillside.

As an analogue, you can also specify the mesh material for the slope stabilization system according to the EPO patent for invention No. EP 2712961 (A1) dated 09/28/2012, IPC: E01F 7/04, published on 04/02/2014, which is made in the form of a grid and contains at least one metal cable zigzag along the netting, and in which opposite to each other or connected lines of the cable points are connected using clamps with the formation of a continuous structure of a mesh material with many diamond-shaped inner grids. All internal grids have an equal size, which is determined depending on the traction force that the mesh material must withstand.

The design of the analogue according to the EPO patent for invention No. EP 2712961 (A1) is similar to the construction of the above described analogue according to the Russian patent for utility model No. 116514 and is a cover grid, with the same drawbacks - the possibility of stabilizing the slope with its cover does not fully meet the tasks of strengthening landslide and avalanche slopes, because it does not protect against falling rock debris and the descent of avalanches from overlying slopes.

As the closest technical solution with a rigidly fixed frame (prototype), a network avalanche element with an umbrella-like structure was selected according to PCT application for invention No. WO 97/37085 of 03/29/1996, IPC: E01F 7/04, published on 09/10/1997. , which describes a network device of a rigid structure in the form of a rack with fastening fasteners at the end of the rack, and each rack can be straight, angular or curved. A similar design of the umbrella was achieved by using a system of rods radially spaced, of which there are at least three, and connected to a central rod. To reduce the load on the fastening points of the rods, the far ends of the rods are tied with an annular cable (cable) and are additionally attracted to the anchor point at the anchor point, and the main attachment of the structure to the anchor is provided by the central rod. Adjust the load on the radial rods by changing the length of the annular cable.

A common feature of the prototype and the claimed technical solution is that separate panels are used, and, apparently, the umbrella structure of each such panel pursues the idea of the ability of each panel to reach different angles to the slope, similar to the claimed solution. However, in this case, the design of each pillar (panel) in the form of a curved structure leads only to the local effect of delaying some stones falling at different angles, the trajectory of which is directed specifically to this particular panel. While in the case of the proposed solution by applying the trapezoidal shape of each panel, it is easy to mount a number of such panels of almost any configuration, depending on the configuration of the slope and the angle of inclination of the overlying layers. This helps in the application of the proposed solution to predict the possibility of large fractions coming off the upper sections of the slope and to prevent their further downward movement more efficiently.

There is a significant difference between the complex panel system in the prototype, with the use of an umbrella structure that is vulnerable to operating under real conditions from the claimed trapezoidal frame panel.

The difference from the claimed technical solution is also that the ends of the annular cable in the prototype are attracted to the central rod.

In a prototype avalanche avalanche element with an umbrella-like structure, by changing the length of two cables, the mesh tilt can be changed, and due to the possibility of cable slipping under load, the cable is pulled through the rod and the ring is compressed, which leads to shock absorption and load distribution, which reduces the cross-section of the elements . Moreover, since the attachment point is one and is located at the end of the rod, the attachment point can be attached to the anchor or to any other strong point located above or below the surface of the earth, and the grid is evenly fixed along the contour that is specified by the cable. Rollers / bearings are also used when installing several elements, this element is also absent in our design.

It should be noted that for the strength of the entire structure, all the mesh attachment points must be equally strong, and this is technically difficult to achieve in real conditions of mountain slopes. Perhaps that is why the prototype used rollers / bearings when installing several elements - this leads to a rise in price, in fact characterizes the prior art and therefore is absent in the claimed design.

The difference from the prototype is that in the claimed technical solution there are no radially spaced rib elements. Also, in the claimed technical solution there is no basic fastening of the structure to the anchor using the central rod, therefore our technical solution is significantly different from the prototype - in the prototype the ends of the annular cable are attracted to the central rod, which is a difference from the claimed technical solution, from four to five separate cables.

The main difference is that in the prototype each umbrella-type element is a stand-alone device with local fastening to the slope. The combination of several elements in a linear system with their equal strength connection to each other in the prototype is impossible without disrupting its working function.

The purpose of the development of the proposed technical solution is to expand the functionality of the landslide panels with the efficiency of absorption of the kinetic energy of falling stones and snow avalanches on a mountain slope when securing the slope.

The technical task is to create a universal mesh panel for a protective anti-landslide structure with the possibility of further installation, depending on the layout of the panels on the slope with a long trapezoid base up or down, at an angle to the surface of the slope with the formation in terms of a straight line of construction or a concave / curved arc, with a vertical the position of the plane of the mounted panels or their inclination relative to the slope. The listed technical problems are solved with the help of easy-to-use, capable of composing a variety of configurations of anti-landslide designs of mesh panels.

The essence of the claimed technical solution lies in the fact that the mesh panel for the anti-landslide protective structure is a rigid frame with a main mesh fixed to it and an additional finer mesh, the mesh panel frame being a supporting steel frame made in the form of a trapezoid and provided with fasteners, symmetrically located relative to the horizontal and vertical axis of the panel, in order to be able to connect the panels to each other in a row, while the main grid is made and h intersecting reinforcing bars, and the additional mesh is a fine-mesh double torsion wire connected to a layer of mesh geotextile, jointly fixed on a support cable stretched over a supporting steel frame, placed around the perimeter of the panel. In this case, the main mesh can be made in the form of a reinforcing mesh or mesh from a cable with a large cell. In this case, the additional mesh can be made flexible and can be a layer of geotextiles (geogrids, geogrids) or geotextiles in combination with a flexible steel mesh.

Based on the described essence of the claimed technical solution, we can consider the claimed solution as a combination of means having the same purpose. Moreover, each tool from this combination - a rigid frame, the main grid in the form of intersecting reinforcement rods or coarse mesh of a cable, an additional grid in the form of a rigid or flexible structure - affects the achievement of the overall technical result, namely, increasing the functionality of protecting the slope from landslides with the maximum considering the configuration of the slope and overlying strata. The signs of the implementation of the main grid in the form of a grid of a cable with a large cell and an additional grid flexible in the form of a geotextile layer are special cases of the implementation of the relevant essential features expressed by generalized concepts with the achievement of the same result that is ensured by a combination of essential features, namely the placement of the main and additional rigid trapezoidal mesh

In the anti-landslide embodiment, additionally, in order to fix the slope, the space between the fixed slope and the rows of mesh panels is filled with drainage soil with layer-by-layer compaction, forming terraces. The number of rows of panels and the distance between them is determined by the required number and width of terraces. In the case of using a protective structure made of metal mesh panels for terracing the slope in order to combat soil erosion or for the restoration of disturbed slopes, mesh panels are arranged in rows across the slope and are connected by fasteners within each row.

The claimed technical solution is illustrated by drawings.

FIG. 1, Panel design, where:

a) panel filled with reinforcing mesh

1 - hard frame;

2 - reinforcing mesh;

b) a panel with a two-layer mesh filling

3 - support cable around the perimeter of the panel;

4 - mesh cable with a large cell;

5 - a mesh of double torsion wire with a small mesh;

6 - supporting steel frame.

FIG. 2, Installation of panels on a slope, where:

7 - panel;

8 - fasteners;

9 - supporting rod;

10 - soil anchor.

FIG. 3. The scheme of the mesh panel.

The design of the mesh panel (Fig. 1) is presented in two versions: in the form of a rigid frame 1 filled with reinforcing mesh 2 (Fig. 1a) and in the form of a support cable around the perimeter of panel 3 with filling with a mesh from a cable with a large cell 4, mesh from double torsion wire with a shallow mesh 5 and a supporting steel frame 6 (Fig. 1b). The protective structure of metal mesh panels on the hillside (Fig. 2) is designed to absorb the kinetic energy of falling stones and snow avalanches and contains panels 7, arranged in rows across the slope by means of fasteners 8 and attached to soil anchors 10 previously embedded in the slope, by support rods 9.

The inventive mesh panels in the framework of the protective anti-landslide design work as follows (Fig. 3). To absorb the kinetic energy of falling rocks and snow avalanches on a mountain slope, falling rocks are captured by mesh panels installed in rows across the slope in several tiers along the height of the slope. The shock loads are partially absorbed by the elastic deformations of the mesh elements of the panel filling, and the remaining unabsorbed part of the shock load is transmitted through the system of support bars of the frame beams and cables and is perceived by soil anchors embedded in the slope to which the cables are attached.

Compared with the known, the claimed design has versatility, the scope of the claimed design is much wider, the claimed design allows you to comprehensively solve the issues of engineering protection of mountain slopes.

The possibility of multiple reproduction of the claimed design stems from the method of its industrial configuration, which allows you to reproduce the protective structure from the same metal mesh panels, if necessary, in different environmental conditions. A similar combination of versatility, the achievement of the possibility of multiple reproduction with the relative simplicity of the configuration in the prototype has not been achieved.

Based on the foregoing, we can conclude that the claimed technical solution meets the criteria of "novelty" and "industrial applicability".

Claims (1)

The mesh panel for the anti-landslide protective structure, which is a rigid frame, characterized in that the main mesh and an additional finer mesh are fixed to the rigid frame, the mesh panel frame being a supporting steel frame made in the form of a trapezoid and provided with fasteners symmetrically located relative to horizontal and vertical axis of the panel, in order to be able to connect the panels to each other in a row, while the main grid is made of intersecting reinforcing bars It is flexible, and the additional mesh is made flexible and is a fine-mesh double torsion wire connected to a layer of mesh geotextiles, jointly fixed on a support cable stretched over a supporting steel frame, placed around the perimeter of the panel.

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