RU187052U1 - WIRE WIRE Mesh FOR PROTECTIVE SYSTEMS WITH HIGHER PLASTICITY - Google Patents

Abstract

The utility model relates to construction and is used in the construction of protective systems - mesh structures used to strengthen slopes, protect soil from erosion, fasten mine workings in mines and mines, and protect against rockfalls and avalanches. The technical result of the proposed utility model is to increase the ductility of the shape of the mesh, which allows for a tight fit of the relief of the protected slope with the mesh. The solution to the technical problem in a braided wire mesh for protective systems with increased ductility laid on a protected surface, woven from corrosion-resistant single spiral-twisted steel wires in which the wires have an angle of inclination α, is achieved by the angle of inclination of the wire α lying in in the range of 10-14.9 °, the wire material has a nominal strength in the range of 290-999 N / mm. The thickness of the mesh web can be in the range of 51-60 mm. 4 ill.

Description

The utility model relates to construction and is used in the construction of protective systems - mesh structures used to strengthen slopes, protect soil from erosion, strengthen mine workings in mines and mines, and protect against rockfalls and avalanches.

A well-known analogue is single woven steel mesh in accordance with GOST 5336-80.

The disadvantage of the analogue is the lack of reliability of the mesh in the protective system. The shape of the mesh cell is rhombic, close to square. This form has a maximum living section - the ratio of the area of the holes to the total area. The specific bearing capacity of such a mesh per unit area compared to a mesh having a rhombic cell shape, more elongated along the direction of application of the load, is lower, ceteris paribus, the thickness and strength of the wire. In addition, with this shape of the cell, the forces arising during operation on the surface of the grid are transmitted from one cell to another almost linearly, almost immediately creating tension on the wire of the grid and moving its grid over the surface that the grid covers, which reduces the reliability of the grid as an element protective system.

A known analogue is a wire mesh for gravel fencing or for protecting the surface soil layer - RF patent No. 2229561, 02.02.1999, adopted as a prototype, laid on the soil surface, or fixed in an almost vertical position on a slope, woven from corrosion-resistant wires, characterized in that the wire in the wire mesh is made of high strength steel having a nominal strength in the range of 1000-2200 N / mm ² , and as

such a steel wire, twisted wire or spring steel wire is used, woven from single spiral-shaped bent wires, as a result of which the wires respectively have an angle of inclination α, preferably in the range of 25-35 °.

The disadvantage of the prototype is the lack of flexibility of the mesh, which is required for a tight fit of the mesh relief of the protected slope.

The technical task of the utility model is to provide a tight fit of the relief of the protected slope with the grid.

The technical result of the proposed utility model is to increase the ductility of the mesh web, which allows for tight fit of the relief of the protected slope by the mesh.

The solution of the technical problem in a braided wire mesh for protective systems with increased ductility laid on a protected surface, woven from corrosion-resistant single spiral-twisted steel wires, in which the wires have an angle of inclination α, is achieved by the angle of inclination of the wire α in the range of 10 -14.9 °, the material of the wire has a nominal strength in the range of 290-999 N / mm ² . The thickness of the mesh web can be in the range of 51-60 mm.

In FIG. 1 shows a general view of the mesh as part of a protective system.

In FIG. 2 shows a mesh web and an option for fixing the ends of the mesh.

In FIG. 3 shows a side view (view A from FIG. 1) of the web web.

In FIG. 4 shows an embodiment of fixing the ends of the grid.

The braided wire mesh 1 for the protective system shown in FIG. 1, laid on the protected surface 2, it is woven from

corrosion-resistant single helically twisted wires 3, as shown in FIGS. 2, 3, of steel, wire 3 in the grid 1 have an angle of inclination α, shown in FIG. 2, the angle of inclination α of the wire 3 lies in the range of 10-14.9 °, and the thickness T, as shown in FIG. 3, the mesh web 1 lies in the range of 51-60 mm. The nominal strength of the wire 3 mesh is in the range of 290-999 N / mm ² .

Consider an example of a specific implementation of a braided wire mesh for protective systems with increased ductility. For the manufacture of mesh 1 with an angle of inclination of the wire α = 14 °, thickness T = 55 mm, steel wire 3 with a thickness of 3.2 mm is used, having a strength of 340 N / mm ² , which has the plasticity required to achieve a technical result, guaranteeing the ductility of the mesh fabric 1. Made from a material with a strength of more than 1500 N / mm ^{2 the} wire has less ductility and will not allow the achievement of the specified technical result. Mesh 1 having an inclination angle of more than 14.9 degrees and a two-dimensional structure (T <15 mm), with tension arising in the design of the protective system using mesh 1 mentioned in the description of the prototype deficiency, has less ductility and the ability to deform in accordance with the relief the surface of the protected slope. The wire 3 is pre-coated with zinc for additional protection against corrosion, which increases the protection of the wire from destruction. Then, on an automatic machine line, wire 3 is bent into spiral segments that weave together to form a net of mesh 1. When weaving wire 3 by setting the equipment of the automatic machine line and replacing a special mandrel, the angle of inclination α of the wire relative to the longitudinal direction 7 is 10 degrees. When the angle α is less than 10 degrees, mesh 1 has increased material consumption and specific gravity, which reduces the manufacturability of manufacturing a mesh structure of the protective system. When the angle α is more

14.9 degrees the shape of cell 8 of grid 1 is close to square. A grid with a square cell shape has a lack of prototype — lack of a deformation margin and low ductility. By adjusting the equipment of the automatic machine line and replacing the special mandrel, the thickness T of mesh 1 is set equal to 60 mm in the example, as shown in FIG. 3. The thickness T of the mesh 1 provides a margin of deformation of the mesh 1, as well as the shape of the cell 8. With a small thickness T of the mesh 1, it is two-dimensional, its margin of deformation and ductility are small, therefore, it has a disadvantage of the prototype. A mesh with a thickness of 60 mm has optimal ductility, and with an increase in thickness, manufacturability decreases, transportation is difficult, therefore, the upper limit of thickness is limited to 60 mm.

Let us consider an example of the operation of a braided wire mesh for protective systems with increased ductility. Mesh 1 is used to protect slope surface 2, as shown in FIG. 1. The protective system of the slope consists of a mesh 1 and fastening elements of the mesh 1 to the surface 2 - anchors (not shown in Fig.). During installation, the grid is laid so that it goes around the relief and presses all the objects on the slope, for example, stones. This eliminates the movement of objects on the slope, which can lead to shedding of the slope. During operation, mesh 1 is subjected to loads of the weight of the retained soil and stones, as well as to the loads resulting from human activities. When a load is applied to one cell 8 of the grid 1, for example, during the installation of the grid 1, and the presence of a stone protruding strongly on the surface 2, the grid is deformed, showing its plasticity. Mesh 1 can be deformed in the protective system of rocky slopes from the influence of the weight of the breakaway part of the rock or in the mine as a result of the collapse of the rock, as well as from the influence of the human factor - mesh 1 is hooked. In these cases, the deformation reserves laid by the angle α, the flexibility of the material and the thickness T of the mesh 1 are consumed, providing the required ductility of the mesh, providing

tight fit of all slope objects. When using the grid in mines with high humidity and salt concentration, intense corrosion of steel occurs. To prevent damage to the mesh due to corrosion, a zinc coating of the wire 3 of the mesh 1 is applied. Each end 4 of the wire 3 on both sides of the mesh 1 is bonded to the end 5 of the adjacent wire of the mesh 1, as shown in FIG. 4, by twisting the ends into a loop. This ensures protection of the grid from loss of integrity as a result of the application of load to wire 3 and from the destruction of individual wires of the grid as a result of loss of integrity of the grid.

The technical result of the utility model is achieved due to the fact that:

- the angle of inclination of the wire α lies in the range of 10-14.9 °, which provides plasticity of the shape of the mesh due to the possibility of deformation in the direction across the small diagonal of the rhombus of the mesh cell,

- the material of the wire has a nominal strength in the range of 290-999 N / mm ² , which ensures plasticity of the shape of the mesh due to the flexibility of the wire,

- the thickness of the mesh cloth lies in the range of 51-60 mm, which ensures the plasticity of the shape of the mesh due to the possibility of deformation with a change in the thickness of the mesh.

Claims (2)

1. Braided wire mesh for protective systems with increased ductility, laid on a protected surface, woven from corrosion-resistant single helically twisted steel wires, in which the wires have an angle of inclination α, characterized in that the angle of inclination of the wire α lies in the range of 10 -14.9 °, the material of the wire has a nominal strength in the range of 290-999 N / mm ² . 2. Braided wire mesh for protective systems according to claim 1, characterized in that the thickness of the mesh fabric lies in the range of 51-60 mm.

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