FI20206164A1 - Steel wire mesh for mining and other subterranean constructions - Google Patents

Abstract

The invention relates to a wire mesh for supporting the walls of mines or other underground structures. The net comprises a number of rectified first net wires, which are arranged at a first distance from each other, and a number of rectified second net wires, which are arranged at a second distance from each other at a right angle in relation to the first net wires. The first and second mesh wires are attached to each other at the point of intersection of the mesh wires, advantageously by welding. The net also includes third net wires aligned with the first net wires, whereby a single third net wire is arranged at a maximum distance of 20 mm from the first net wire, when the number of third net wires is less than the number of first net wires.

Description

STEEL WIRE NETTING FOR MINES AND OTHER UNDERGROUNDS

FOR STRUCTURES The subject of the invention is a steel wire mesh for supporting the walls of mines and other underground structures. In particular, the object of the invention is a steel wire mesh according to the preamble of the independent claim. A net made of steel wire, so-called — mining net, is attached to the walls of mining tunnels and similar underground structures, for example parking caves, to strengthen the structure itself and to prevent loose and/or loose stones from falling. The mining net used must follow the walls of the structure, so the mining net must be made of a suitably soft wire. Depending on the intended use, certain strength requirements have been set for the net, so that the structure made of it is safe and meets the regulations. However, the mining net must be — relatively easily moldable, so that it can be mechanically pressed to conform to the tunnel walls. The purpose of the present invention is to further develop the solutions of the known technology, as well as to eliminate or at least reduce the — problems in the known technology. One of the purposes of the invention is a steel wire mesh that is easily moldable and meets the required strength and other requirements.

S a 25 In order to realize these purposes, the steel wire mesh according to the invention is N mainly characterized by what is presented in the characterizing part of the independent claim.

T a S Some advantageous S 30 — embodiments of the invention are presented in other, independent patent claims.

N A typical steel wire mesh according to the invention for supporting the walls of mines and other underground structures, comprises

- a number of parallel first mesh wires, which are arranged at a first distance from each other, - a number of parallel second mesh wires, which are arranged at a second distance from each other, at right angles to the first mesh wires, which first and second mesh wires are attached to each other at the crossing points of the mesh wires, preferably by welding, and - third mesh wires parallel to the first mesh wires, where a single third mesh wire is arranged at a distance of no more than 20 mm from the first mesh wire, the number of third mesh wires being smaller than the number of the first mesh wires.

Now, it has been surprisingly discovered that by arranging a third mesh wire next to the first mesh wire at a maximum distance of 20 mm from the first mesh wire in a part of the net, a steel wire mesh can be produced that is extremely durable, but at the same time easily shaped, so that it can simply be mechanically pressed to follow the walls of the tunnel.

The steel wire mesh according to the invention comprises a number of parallel first mesh wires, which are arranged next to each other at a first distance from each other, and a number of parallel second mesh wires, which are arranged side by side at a second distance from each other, at right angles to the first mesh wires.

The first mesh wires N can therefore be thought of as being arranged vertically, and the second mesh wires horizontally. = 25 The first distance between the first mesh wires can be 45 — 150 mm, N preferably 45 — 100 mm, more preferably 45 — 70 mm.

The > second distance between the other mesh wires can be 45 — 150 mm, preferably 45 — 100 mm, more preferably 45 — E 70 mm.

In one embodiment, the first distance S between the first mesh threads may be different from the second distance S 30 between the second mesh threads.

In a steel wire mesh, the distances between the first mesh wires are N usually the same, i.e. the first distance does not vary in a single mesh.

Correspondingly, the distances between the other net threads are also usually the same, i.e. the second distance does not vary in one net.

The first and second mesh wires are attached to each other at the crossing points of the mesh wires, preferably by welding, to form a steel wire mesh.

When making the net, the wire used for the net is cut to the desired size, and the cut wire parts form the described net-like structure, i.e. a wire net, and the overlapping net wires in the structure are welded to each other at the points where the wires cross.

Now — in the present = invention = third mesh wires parallel to the first mesh wires are arranged in the mesh structure of the steel wire mesh.

The third mesh wire is arranged relatively close to the first mesh wire, at a distance of at most 20 mm, preferably at most 15 mm, more preferably at most 10 mm, from the first mesh wire.

This distance is so small that, for example, the bolts intended for fixing steel wire mesh cannot fit between the first and third wire.

According to one embodiment of the invention, the distance of the first mesh wire to the third mesh wire can be between 0 and 20 mm, preferably between 2 and 20 mm, more preferably between 2 and 15 mm, even more preferably between 5 and 10 mm.

The distance between the first and third mesh wire is measured from the outer surface of the third mesh wire to the outer surface of the nearest — first mesh wire.

Advantageously, only one third mesh wire is arranged in the immediate vicinity of the first mesh wire.

The third mesh wire is therefore arranged next to the first N mesh wires, either on its first or second side.

If third = 25 — mesh wires are arranged in the immediate vicinity of several separate first mesh wires N, each third mesh wire is arranged on the same side > of each first mesh wire, so all mesh wires are arranged E on the same side of the first mesh wires, either on the first or second S side.

S 30 N In steel wire mesh, the number of third mesh wires is smaller than the number of first mesh wires.

In practice, this means that third mesh wires are arranged in the immediate vicinity of the first mesh wires only in certain parts of the steel wire mesh. Parts of the wire mesh where the third mesh wires are arranged close to the first mesh wires can be called reinforcement areas.

In one embodiment, third net yarns are arranged only adjacent to certain first net yarns. If the steel wire mesh then comprises several reinforcement areas, all reinforcement areas are parallel.

In another embodiment, the steel wire mesh can also comprise third mesh wires parallel to the other mesh wires, in which case the individual third mesh wire is arranged at a distance of no more than 20 mm, preferably no more than 15 mm, more preferably no more than 10 mm, from the second mesh wire, the number of third mesh wires being smaller than the number of other mesh threads. The distance of the second mesh wire to the third mesh wire can be between 0 and 20 mm, preferably between 2 and 20 mm, more preferably between 2 and 15 mm, even more preferably between 5 and 10 mm. The distance between the second and third mesh wire is measured from the outer surface of the third mesh wire to the outer surface of the nearest second mesh wire. — In yet another embodiment, the steel wire mesh can comprise third mesh wires parallel to the first and second mesh wires. In this case, the reinforcement areas of the steel wire mesh intersect in some part of the steel wire mesh. N In one embodiment of the invention, the steel wire mesh can comprise at least = 25 — two reinforcement areas, where a third mesh wire is arranged in the immediate vicinity N of the first and/or second mesh wire. Each reinforcement area can comprise > at least two, preferably at least three, adjacent first and/or second E mesh wires. This means that each reinforcement area comprises at least two S parallel first and/or second mesh wires, preferably one third mesh wire is arranged in the immediate vicinity of each S 30 — . A number of individual first and/or second mesh wires remain between adjacent N reinforcement areas, in the immediate vicinity of which, at a distance of less than 20 mm, no third mesh wire is arranged. The distance between adjacent reinforcement areas can be between 65 and 250 cm. The distance between adjacent reinforcement areas can be, for example, 65 — 115 cm, especially if at least three parallel reinforcement areas are arranged in the steel wire mesh.

5 —Reinforcement areas, where a third mesh wire is arranged next to the first and/or second mesh wire, can be arranged on the parallel edges of the mesh. If reinforcement areas are arranged only on the parallel edges of the steel wire mesh, the distance between them can be, for example, 120 — 250 cm. In one embodiment, all edges of the network are provided with a — gain zone. In addition, the steel wire mesh can advantageously comprise at least one central reinforcement area, which is arranged between the reinforcement areas arranged at the edges of the mesh. In this case, at least three reinforcement areas are arranged in the steel wire mesh. — If — the steel wire mesh — comprises reinforcement areas arranged on — the edges — and in addition at least one central reinforcement area, said at least — one central reinforcement area and the reinforcement areas arranged on the edge may comprise a different number of first and/or second mesh wires, next to which a third mesh wire is arranged. In practice, this means that the width of the reinforcement areas at the edges of the network differs from the width of the central reinforcement area or areas.

— The width of the individual reinforcement area can be 100 — 500 mm, preferably 150 — 400 mm. The width of the reinforcement area arranged at the edge of the net can be 100 — 300 mm, preferably 150 — 300 mm, and the width of each individual central reinforcement area can be 150 — 500 mm, preferably 220 — 400 mm. The width of the reinforcement area is measured as the distance between the outer sides of its N outermost wires. = 25 N If the steel wire mesh includes third mesh wires parallel to both the first and second mesh wires >, the steel wire mesh has at least E one first and one second reinforcement area, which are at a right S angle to each other and cross the steel wire mesh at some point. The steel wire mesh S 30 can have several first and/or second reinforcement areas.

O

N The diameter of the first mesh threads can be 3 — 6 mm, preferably 4 — 5.5 mm, more preferably 5.5 mm.

The diameter of other mesh wires can be 3 — 10 mm, preferably 3 — 9 mm, more preferably 4.5 — 8.5 mm, sometimes more preferably 8 mm.

The diameter of the third mesh wires can be 3 — 10 mm, preferably 3 — 9 mm or 3 — 6 mm, more preferably 4 — 5.5 mm, sometimes more preferably 5.5 mm.

The diameter of the third mesh wire is at most equal to the diameter of the first and/or second mesh wire in the immediate vicinity of which the third mesh wire is arranged.

The diameter of the third mesh wire can be equal to or smaller than the diameter of the first and/or second mesh wire in the immediate vicinity of which the third mesh wire is arranged.

In an advantageous embodiment of the invention, the diameter of the second mesh threads can be larger than the diameter of the first mesh threads.

In particular, if — third mesh wires are arranged mainly or only next to or in connection with the first mesh wires, the diameter of the first mesh wires can be smaller than the diameter of the second mesh wires.

The diameter of the third mesh wires can be the same as the diameter of the first and/or second mesh wires.

If third mesh wires are arranged in connection with both the first and second mesh wires, the first and second mesh wires are preferably of the same diameter.

N In a preferred embodiment, third mesh threads are arranged = 25 only next to the first mesh threads, in which case the diameters of the first and N third mesh threads are identical and 3 — 6 mm, preferably 4 — 5.5 > mm, more preferably 5.5 mm.

The diameter of the second mesh wires is then larger than E the diameter of the first mesh wires and is 3.5 — 9 mm, preferably 4.5 — 8.5 mm, S more preferably 8 mm.

S 30 N The wire used as a mesh wire can be a wire made of steel by hot rolling, which preferably has a substantially circular cross-section.

In the steel wire mesh according to the invention, for example, rolled wire can be used, with an elongation at break (A10) of about 20 — 35%. Typically, the breaking strength Rm of the mesh wire is about 370 — 450 N/mm? and the yield strength Reo,20 is about 320 — 400 N/mm?. —An embodiment of the invention is described in more detail in the attached figure 1, which illustrates a steel wire mesh according to an embodiment of the invention. Figure 1 shows a steel wire mesh A, which comprises parallel first mesh wires 1, 1' and parallel second mesh wires 2, 2. — In the shown steel wire mesh, the distance between the first mesh wires 1, 1' is roughly the same as the distance between the second mesh wires 2, 2'. The openings formed in the steel wire mesh are therefore essentially square. The first mesh wires 1, 1' and the second mesh wires 2, 2' are attached to each other at the crossing points x, x' of the mesh wires, usually by welding.

The steel wire mesh A also comprises third mesh wires 3, 3' parallel to the first mesh wires 1, 1. The third mesh wires 3, 3 are arranged in the immediate vicinity of some of the first mesh wires 1, 1', at a maximum distance of 20 mm from the first mesh wire 1, 1'. Thus — reinforcement areas 4, 4 are formed in the steel wire mesh, where third mesh wires 3, 3' are arranged in the immediate vicinity of the first mesh wires 1, 1'. Reinforcement areas 4, 4 have been formed at the edges A, A" of the steel wire mesh A" and in its middle. In the embodiment shown in the figure, the N reinforcement areas 4 arranged at the edges A', A" of the steel wire mesh A are narrower than = 25 — the central reinforcement area 4' formed in the middle of the mesh A". n - The invention is not intended to be limited to the exemplary embodiments E shown above, but the invention is intended to be widely applied within the scope of the — patent claims = defined — inventive = idea S 30 — defined in the following S.

S

Claims (15)

STANDARD 1. Steel wire mesh for supporting the walls of mines and other underground structures, which mesh comprises - a number of parallel first mesh wires arranged at a first distance from each other, - a number of parallel second mesh wires arranged at a second distance from each other, at right angles to the first mesh wires, which and the second mesh wires are attached to each other at the crossing points of the mesh wires, preferably by welding, characterized in that the steel wire mesh comprises third mesh wires parallel to the first mesh wires, in which case the individual third mesh wire is arranged — at a maximum distance of 20 mm from the first mesh wire, the number of third mesh wires being smaller than the number of the first mesh wires . 2. A steel wire mesh according to claim 1, characterized in that the diameter of the second mesh wires is larger than the diameter of the first mesh wires. 3. A steel wire mesh according to claim 1, characterized in that it comprises third mesh wires parallel to the other mesh wires, whereby a single N third mesh wire is arranged at a maximum distance of 20 mm from the second = 25 — mesh wire, the number of third mesh wires being smaller than the number of N second mesh wires. i a 4. Steel wire mesh according to claim 1 or 3, characterized in that the distance S of the first and/or second mesh wire to the third mesh wire is O — S 30 20 mm, preferably 2 — 20 mm, more preferably 2 — 15 mm, even more preferably 5 — 10 O N e.g. 5. A steel wire mesh according to one of claims 1 to 4, characterized in that the mesh comprises at least two reinforcement areas, where a third mesh wire is arranged next to the first and/or second mesh wire. 6 A steel wire mesh according to claim 5, characterized in that each reinforcement area comprises at least two, preferably at least three, adjacent first and/or second mesh wires. 7. A steel wire mesh according to claim 5 or 6, characterized in that reinforcing areas are arranged on the parallel edges of the mesh. 8. A steel wire mesh according to claim /, characterized in that the mesh comprises at least one central reinforcement area, which is arranged between the reinforcement areas arranged at the edges. 9. A steel wire mesh according to claim 8, characterized in that at least one central reinforcement area and the reinforcement area arranged at the edge comprise a different number of first and/or second mesh wires, next to which a third mesh wire is arranged. 10. A steel wire mesh according to one of claims 1 to 9, characterized in that the first distance between the first mesh wires is 45 to 150 mm, preferably 45 to 100 mm, more preferably 45 to 70 mm. O a 25 11. A steel wire mesh according to any of claims 1 to 10, characterized in that the second distance between the N second mesh wires is 45 to 150 mm, preferably 45 to 100 mm, more preferably 45 to 70 mm. T a S 12. A steel wire mesh according to one of claims 1 — 12, characterized in that the diameter of S 30 — the first mesh wires is 3 — 6 mm, preferably 4 — 5.5 mm, more preferably 5.5 mm. 13. A steel wire mesh according to any of claims 1 to 13, characterized in that the diameter of the other mesh wires is 3 to 10 mm, preferably 3 to 9 mm, more preferably 4.5-85mm. 14 A steel wire mesh according to one of claims 1 to 13, characterized in that the diameter of the third mesh wire is at most equal to the diameter of the first or second mesh wire. 15. A steel wire mesh according to one of claims 5 to 14, characterized in that — the distance between adjacent reinforcement areas is between 65 and 250 cm, preferably 65 and 115 cm or 120 and 250 cm. O OF O OF Q I a a < O O O OF O OF