EA019260B1 - Method of construction of protective net for falling rock or the like - Google Patents

Abstract

A method of construction of a tightly-fitted protective net by which the net is closely attached to a slope surface so as to stably prevent loose rock from falling and stony earth from sliding down and flowing out, while the growing environment for plants can be maintained. The net is laid on the slope surface, a plurality of vertical and horizontal ropes, of which both ends are respectively fixed by anchors, are stretched on the net at intervals. Intersections of the vertical and horizontal ropes are fixed by anchors, besides, weir bodies are arranged on the net sections surrounded by the vertical and horizontal ropes, and the weir bodies are locked by a plurality of anchor rods to bring the net sections into pressure contact with the slope surface.

Description

The present invention relates to a method for constructing a tight contact protective mesh to be installed on a slope of a slope or the like. against rockfall or falling gravel or soil.

On slopes formed by hillsides or mountain slopes of mountains or hills, as a countermeasure against the danger of rockfall, landslides, etc., a method of constructing a protective net is carried out by laying a net along the slope, placing vertical and horizontal cables on the net and securing the intersections of vertical and horizontal cables to the slope by means of anchors together with the mesh.

However, many parts of the surfaces of slopes have irregular and unstable landforms due to partial exposure of rocks or the presence of unstable stones, gravel and soil, etc. As a result of this, there is a problem in that the vertical and horizontal cables and the mesh do not come into sufficiently tight contact with the surface of the earth only by driving the anchors into the slope, and therefore it is impossible to reliably prevent the fall of unstable stones.

To solve this problem, 1P-L-7-300819 proposed the use of a protective mesh by nailing in the slope of many rod anchors with hooks having a hook-shaped locking section formed on the lower side of their head section, engaging vertical cables, horizontal cables or mesh on hook-shaped locking sections of rod anchors, thereby fixing them on the slope.

The use of a protective net is a system for introducing the net into tight contact with the slope by engaging vertical ropes, horizontal ropes or mesh on hooks. Since the turning of unstable stones is prevented by rubbing the mesh at the points where the hooked rod anchors are driven in, it seems that rolling of the stones is to some extent prevented.

However, since the action of each rod anchor with a hook that comes into tight contact with the mesh is limited to a small area, like a stain, the effect of preventing rolling and falling of unstable stones is not satisfactory. As a result, in order to improve the degree of tight contact of the mesh with the slope, an extremely large number of rod anchors with hooks is necessary for hammering, which leads to the problem of increasing labor costs and cost.

In addition, if a slip-fall effect occurs, in which gravel and soil (including pebbles) slide downward due to rain or weathering, their fall energy exceeds the resistance forces in the spot of the wire mesh pressed by rod anchors with hooks, and it cannot be prevented downward sliding of gravel and soil in the gap between the surface of the earth and the wire mesh. Therefore, the problem arises that such a sliding fall of gravel and soil causes a new gap between the surface of the soil and the grid, thereby creating new unstable stones and causing the stones to roll.

In order to solve the problems described above, an object of the present invention is to provide a method for constructing a tight-contact protective mesh that is able to reliably bring the mesh into tight contact with the slope, thereby strongly protecting against the fall of unstable stones, the sliding fall and runoff of gravel and soil, thus so that you can save the environment for the growth of vegetation.

To achieve the above objectives, the present invention provides a method of constructing a protective mesh, including laying the mesh on a slope, tightly pulling a plurality of vertical and horizontal cables attached at both ends to the slope by anchors on the mesh, and attaching intersections of vertical and horizontal cables to the slope with anchors, characterized the fact that the locking elements are placed essentially on the Central sections of the necessary sections of the sections of the grid sections surrounded by vertical and horizontal nymi cables, and the locking elements are fixed by a plurality of anchor rods are driven into the layer of gravel and soil, whereby the portions of the grid sections is introduced into pressure contact with the slope planes.

The present invention is intended for tight tension of vertical and horizontal cables on a slanted mesh, attaching cable intersections, locking elements located essentially in the central sections of the necessary sections from sections of mesh sections surrounded and separated by vertical and horizontal cables, and to cause them adhesion to a layer of gravel and soil with a multitude of anchor rods. Accordingly, sections of the grid sections are brought into clamping contact with the slope in the form of planes instead of points in such a way that the desired holding effect in the ground is demonstrated and the sliding fall of gravel and soil in the gap between the ground surface and the wire mesh is reliably prevented. The term necessary sections of sections of the grid sections refers to sections of the grid sections located on the slope areas, where gravel and soil cover the rock formation with a certain thickness.

Also, since a sliding fall of gravel and soil can be prevented in each of the sections of the grid sections separated by vertical and horizontal cables, the effect of a sliding fall of gravel and soil, occurring on the slope part, on the sections of the grid sections surrounded by vertical and horizontal cables can be prevented. lower so that

- 1 019260 Sliding fall may be limited. In addition, since the tight contact between the slope and the section of the mesh section, surrounded by intersections of vertical and horizontal cables, is improved due to the tight-contact action of the locking elements, the fall of unstable stones can be reliably prevented.

In addition, since sliding falling or shedding of gravel or soil can be prevented, the effect of plant growth is accelerated and therefore stabilization of the slope due to vegetation is achieved at an earlier stage, so that the effectiveness of the protection of the slope is significantly improved.

The locking element includes a plate having a width and length overlapping a plurality of cells and a plurality of comb teeth extending downward from the plate at intervals that allow insertion through the cells, which are pointed at their distal end and located on the side portions of the plate, the plate includes many holes to allow the insertion of anchor rods in its central areas.

The locking element includes comb teeth, which form a stop due to cutting into the slope, while the section of the mesh section is brought into contact with the slope by means of a plate. Since the anchor rod includes a flange for pressing the plate on top of the rod, having a length sufficient to reach the gravel and soil layer, and pointed at its distal end, and whose head portion serves as a pinning point on top of the flange, the plate is strongly pressed through the flange by hammering the anchor rod into the layer of gravel and soil, whereby the mesh is brought into pressure contact with the slope using a plate, so that the sliding fall of gravel and soil is prevented and at the same time rolling down unstable stones can also be prevented. As a result, problems can be prevented, such as the accumulation of unstable stones, gravel and soil or fallen rocks in the lower end section of the net, or the protrusion of the net in the direction of the road, thereby blocking quiet transport.

Also, since the comb teeth cut into the slope and form stoppers, gravel and soil are not showered due to wind and rain, and the surface of the slope soil is expectedly preserved. As a result, plant growth is accelerated and weathering of the slope is prevented.

Other characteristics and advantages of the present invention will be disclosed in the detailed description below. However, it is obvious that the invention is not limited to the configuration shown in the embodiment, and various modifications and changes are possible provided that the basic characteristics of the present invention are provided.

The drawings show:

FIG. 1 is a top view of an embodiment of a method of constructing a protective net against a rockfall, and the like. according to the present invention;

FIG. 2 is a cross-sectional view taken along line XX in FIG. one;

FIG. 3 is a side view of a vertical cross section of an end anchor portion;

FIG. 4 is a side view of a vertical cross section of an intersectional anchor section;

FIG. 5 is a perspective view showing an example of a locking member according to the present invention;

FIG. 6 is a front view of a flange anchor rod according to the present invention;

FIG. 7 is a front view showing a locking member in an installation state;

FIG. 8A is a plan view showing a locking member in a use state;

FIG. 8B is a front view showing a locking member in a use state;

FIG. 8C is a side view showing a locking member in a use state;

FIG. 9 is a front view schematically showing the effect of the method of constructing a security net of the present invention.

Below with reference to the attached drawings will be described embodiments of the present invention.

In FIG. 1 and 2 show embodiments of a method for constructing a protective net against a rockfall or the like. according to the present invention.

In the drawings, the conditional sign a denotes a slope at which there is a risk of falling due to rolling of unstable stones, a sliding fall of gravel and soil, etc., the conditional sign c denotes a fixing layer, and the symbol b denotes a layer of gravel and soil covering a rock layer. .

Reference number 1 denotes a grid laid along the slope a. Mesh 1 may be formed

- 2 019260 on fiber, but as a rule, use a wire mesh coated with a corrosion-resistant coating. The wire mesh used in this invention is preferably a thick wire mesh having a thickness of about 30 to 50 mm, which is formed by weaving wires having a diameter, for example, of 3 to 4 mm, in order to reinforce the holding property with respect to land and sand, etc.

On the grid 1, a row of vertical ropes 2a is pulled in parallel at predetermined intervals from each other and a row of horizontal ropes 2a are pulled in parallel at predetermined intervals from each other.

The upper end section and the lower end section of each vertical cable 2a are attached to the slope at the positions on the upper side and the lower side outside the mesh 1 by means of end anchors 3, 3. The left end section and the right end section of each horizontal cable 2b are also attached to the slope at the positions outside the mesh by end anchors 3, 3. FIG. 3 shows an end anchor portion in detail.

Corresponding intersections between the vertical ropes 2a and the horizontal ropes 2b are fastened by means of anchors 4 for intersections that pass through the cells so that the mesh 1 comes into close contact with the slope. In FIG. 4 shows in detail the intersection anchor.

Further, the locking elements 5 are located essentially in the centers of the necessary sections from sections 10 of the mesh sections, which are rectangular zones, separated by surrounding by vertical cables 2a and horizontal cables 2b, and the sections 10 of the mesh sections are brought into contact with the slope surface in cooperation with anchor rods 6.

In this invention, the term “required sections” from sections of 10 sections of the grid does not mean sections of sections of the grid located on sections of the slope where rocks and rocks come to the surface, but means sections of the sections of the grid located on sections of the slope where gravel and soil cover the rock formation with a certain thickness. As a result of this, although the locking elements 5 can be placed on all sections 10 of the mesh sections, the invention is not limited to this, and they can be placed on part of the sections 10 of the mesh sections, as shown in FIG. 1 as an example.

The state of the method for constructing the locking elements 5 is shown in detail in FIG. 8A-8C. The locking member 5 includes a metal plate 5a having a width and height that covers a plurality of cells and a plurality of comb teeth 5b that extend downwardly at the end edge portions of the plate 5a and are long enough to cut into the layer b of gravel and soil. The plate 5a is arranged essentially in the central part of the section 10 of the mesh sections, and the plate 5a is attached by means of a flange anchor rod 6 driven into the gravel or soil layer b, and introduces the section 10 of the mesh sections into the pressure contact with the slope.

The procedure for constructing a safety net according to the present invention will be described in detail. First of all, they clean the slope a, which has a risk of rockfall, etc., from a variety of trees, unstable stones, etc., and then mesh 1 having the required surface area is laid on the slope from top to bottom.

After laying the mesh 1, a row of vertical cables 2a are arranged from top to bottom at the required intervals, and horizontal cables 2b are placed on the mesh 1 one after the other from left to right. The vertical and horizontal cables 2a and 2b used in this invention are, for example, a zinc-coated cable having a diameter of 12 mm with a 3x7 structure. The portions of the vertical and horizontal cables 2a, 2b in contact with the mesh 1 are fastened by means of fastening rings 9, which are steel wires formed with a spiral shape. In FIG. 1 fastening rings are shown in only a few positions.

The ends of the vertical and horizontal cables 2a, 2b are attached to the rock formation with end anchors 3, 3, as shown in FIG. 3. The end anchor 3 includes an anchor rod 33 provided with a series of protrusions 330 formed on its peripheral surface and a pressure plate 34 tightened onto the external thread on the upper portion of the anchor rod 33 with a nut 35. The construction method is continued by filling in an adhesive primer, such as a mortar 32, into the hole 31 for injecting lime mortar formed in the rock formation by a rock drilling machine and the like, inserting the anchor rod 33 there in this state and after the lime has solidified Vågå solution terminal attachment lugs 32 of the vertical or horizontal cable 2a or 2b so as to extend through the upper end portion of the anchor rod 33, and tightening the pressure plate 34 by a nut 35.

The intersection of the vertical and horizontal cables 2a, 2b is fixed by means of the intersection anchor 4 shown in FIG. 4. Anchor 4 for intersections includes an anchor rod 43 provided with a series of protrusions 430 on its peripheral surface and a gripping fitting 44 to be attached to the upper portion of the anchor rod and tightened with a nut 45.

The gripping fitting 44 includes, as shown in FIG. 4, the upper and lower clamping discs 44a, 44b, each of which is formed with transverse grooves on its inner surface, and two sets of nuts with bolts, for example, to tighten the upper and lower clamping discs 44a, 44b. An external thread at the upper end portion of the anchor rod 43 is used as one of

- 3 019260 data of two sets. The method of construction is carried out by filling an adhesive primer, such as lime mortar 42, into the hole 41 for injecting lime mortar formed by a machine for drilling and reaming rocks, etc., and inserting an anchor rod 43 therein in this state. After the lime mortar 42 has hardened, the construction method is carried out by fixing the intersections of the vertical and horizontal cables 2a, 2b between the upper and lower clamping discs 44a, 44b of the clamping fitting and passing the anchor rod 43 through the upper and lower clamping discs 44a, 44b, tightening and securing the upper and lower clamping discs 44a, 44b with nut 45, and in a different position from it, tightening and securing the upper and lower clamping discs 44a, 44b with a nut with a bolt 46.

Thus, a number of sections 10 of the rectangular mesh sections divided by vertical and horizontal cables 2a, 2b, as shown in FIG. 1, are formed by attaching to the slope the intersections of vertical and horizontal cables 2a, 2b and fastening the contact sections of the vertical and horizontal cables 2a, 2b with the mesh 1 using fastening rings 9.

According to the present invention, the respective end portions of the vertical cables 2a and the horizontal cables 2b are attached with anchors 3, 3, and the intersections of the vertical cables and horizontal cables are attached with anchors 4 so as to form a lattice-like mesh. Then, since this grid is combined with the grid 1 by the fastening rings 9, a two-layer grid is formed so that impacting rock fragments and stones, etc. captured by mesh 1, which is an excellent mesh, and captured by a mesh formed of vertical and horizontal cables.

Also, since the corresponding intersections of the vertical ropes 2a and the horizontal ropes 2b are connected in such a way that a net is obtained, the impact energy of rock fragments and the like, which strike at one point of the grid, is transmitted to other vertical and horizontal ropes through intersections and transmitted everywhere to the corresponding anchors 3, 4. As a result, the energy applied to the individual cables is greatly softened, and the sizes of the anchors of the individual vertical and horizontal cables can be reduced.

In addition to these main advantages in the present invention, the necessary sections from the sections 10 of the mesh sections are brought into pressure contact with the slope by means of the locking elements 5. In FIG. 5 shows the position of one locking element 5, and in FIG. 7 shows the position in use.

The locking element 5 includes a metal plate 5a having a width and length overlapping a plurality of cells, and comb teeth 5b extending downward from the end edge portions of the plate 5a and capable of cutting into the gravel and soil layer b.

The plate 5a preferably has a surface area equal to at least 20,000 mm ² in order to press the mesh flat, and, for example, is formed with a rectangular shape equal to 60x440 mm Four to six comb teeth 5b are provided at the front marginal portion and the posterior marginal portion at intervals that allow insertion through the cells. The length of the comb tooth 5b is from 50 to 80 mm, and its distal end is pointed in order to be able to well cut into the layer b of gravel and slope soil. The comb teeth 5b can be made integrally with the plate 5a or can be formed separately from the plate with a steel rod or a flat plate, and then combined with the plate 5a by welding.

A plurality of holes 5c having a diameter of, for example, approximately 10 mm, for inserting the anchor rods 6 through the plate 5a, are arranged in central positions along its width. FIG. 6 shows a flange anchor rod 6 for attaching a plate 5a to a layer of gravel and soil b, which includes a flange 6c having a thickness of 5 mm and a diameter of 20 mm and attached to the upper part of the rod 6a having a length of 500 mm and a diameter of 9 mm, with a pointed end, for example, by welding and the like. The head portion 6b, which serves as a clogging point, is provided above the flange 6c.

In the manufacture of the mesh, each locking element 5 is placed opposite the essentially central part of the section 10 of the mesh section formed with a rectangular shape and divided by surrounding by means of vertical cables 2a and horizontal cables 2b, as shown in FIG. 7. At this time, the plate 5a is positioned so that it extends laterally in the visible plane, that is, so that it extends parallel to the horizontal cable 2b. At this time, the position of the plate 5a is adjusted so that the hole 5c coincides with the cell 100.

Following this, the flange anchor rod 6 is inserted through the hole 5c of the plate 5a and the head portion 6b of the anchor rod 6 is inserted into the impact head 8b of the machine 8 for hammering the anchors and then hammered. Accordingly, the anchor rod 6 is driven deep into the gravel and soil layer b from the slope surface, and the plate 5a is pressed and moved towards the mesh surface using the flange 6c, whereby the comb teeth 5b cut into the gravel and soil layer b, and the plate 5a enters into a strong contact with the section 10 of the mesh section and, therefore, in the pressure contact with the slope. Section 10 of the mesh section is deformed with significant flattening in the thickness direction, as

- 4 019260 is shown in FIG. 8C. Also, since a plurality of comb teeth 5b, 5b aligned in rows on the upper side and lower side are embedded in the b layer of gravel and soil, they serve as stoppers.

FIG. 9 is a drawing showing, in diagrammatic form, the action of the locking element 5. Since the locking element 5, fixed by the flange anchor rod 6, is able to prevent unstable stones from rolling down, its plate 5a introduces the section 10 of the mesh section into the pressure contact with the slope. In addition, since the comb teeth 5b cut into the layer b of gravel and soil, and therefore serve as a fixative in the ground, even though the layer b 'of gravel and soil almost slid down due to weathering, etc., they stop and, therefore, they can be prevented from sliding in the direction down the slope.

In the case where the vertical and horizontal cables 2a, 2b or mesh 1 depart to a large extent from the slope and a large gap forms between the surface of the earth and the mesh 1, depending on the shape of the slope, it is also recommended to use anchor 7 with a hook, as shown in FIG. 2.

An anchor 7 with a hook includes a portion of a downwardly curved hook 7c attached to an upper portion of a pin shaft 7a having a length of 200 mm and a diameter of 9 mm, for example by welding and the like, and is configured to be driven in and fastening with vertical and horizontal cables 2a, 2b or mesh 1, hooked to its hook section, and the head of the machine for hammering anchors installed on its head section. Accordingly, the vertical cable 2a or the side cable 2b together with the mesh 1 or only mesh 1 can be introduced into an additional tight contact with the slope.

In the case where the intervals of the vertical and horizontal cables 2a, 2b are large, the surface areas of sections 10 of the mesh sections surrounded by these horizontal and vertical cables 2a, 2b are respectively increased and, therefore, what needs to be done in this case is to increase the size locking elements 5 or place a plurality of locking elements 5 in parallel in each section 10 of the mesh section and respectively attach them to the anchor rods, which is included in the present invention.

Claims (3)

CLAIM 1. The method of constructing a protective mesh against rockfall in which the grid is laid along the slope, tightly tension a multitude of vertical and horizontal cables attached at both ends to the slope by anchors on the grid, and attach the intersections of vertical and horizontal cables to the slope by anchors, characterized by that the locking elements are placed essentially at predetermined central sections of the grid sections, surrounded by vertical and horizontal cables, and the locking elements are fixed by means of sets anchor rods driven into a layer of gravel and soil, whereby sections of the mesh sections are introduced into pressure contact with the slope planes, and the locking element includes a plate having a width and length overlapping a plurality of cells and a plurality of comb teeth extending down from the plate at intervals that allow insertion through the cells, which are pointed at their far ends and located on the side portions of the plate, while the plate includes a plurality of holes to allow The introduction of anchor rods in their central areas. 2. The method of construction of a protective mesh against rockfall according to claim 1, in which the locking elements are selectively placed on the section of the mesh section located on the slope areas, while the gravel and the soil cover the rock formation with a certain thickness. 3. The method of constructing a protective mesh against rockfall according to claim 1, wherein the anchor rod includes a flange for pressing the plate on the upper portion of the core, which is long enough to reach a layer of gravel and soil, and pointed at its far end, and a head portion that serves as a driving point over the flange.