KR101638783B1 - Falling stone prevention fence of dual connection structure with improved safety - Google Patents

Abstract

The present invention relates to a falling-stone preventing facility of a dual connection structure with improved safety. Cross-shaped couplers are arranged on the top of a falling-stone preventing net for preventing falling stones in a lattice form. Wire ropes and the couplers are connected by tension springs. The adjoining wire ropes around the couplers are connected to additional auxiliary ropes, thus an emergency that the tension springs are cut is prevented. In addition, a state identification plate easy to recognize the outside is installed at intersecting points of the auxiliary ropes to be separated when the tension springs are cut, thus a manager of the falling-stone preventing facility is able to easily check an abnormal wire rope connection state with the unaided eye.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a double-

The present invention relates to an anti-rocking facility in which a rockfall prevention net is provided on a mountain slope and a wire rope is connected to prevent an accident of preventing a rockfall on the road side.

Mountain slopes around mountainous national roads and railroad tracks are always exposed to the risk of falling rocks, which leads to secondary landslides such as road crashes as well as vehicle crashes. In order to prevent such accidents, a preventive facility using a net is installed on a mountain slope, and generally, a rockfall prevention system is installed in which a plurality of wire ropes are vertically connected on the slope protection network. Generally, a connecting device is used in which wire ropes are crossed to be perpendicular to each other, brackets are installed at intersecting points, and anchors are inserted into brackets so as to be perpendicular to the surface of the mesh and inserted and fixed on the mountain slopes. Such conventional connecting devices are effective for supporting rocks, but they fail to disperse the load of the rockfall and are fixed to tighten the wire rope so that it is difficult to buffer shocks of the rockfall.

In order to overcome such a problem, Korea Patent No. 10-0859209 suggests an elastic compression-type rockfall preventing network capable of effectively absorbing impact applied to a rockfall preventing network by using the spring's elasticity. Specifically, a wire rope is disposed on the surface of a fall-prevention network, and a binding plate is fixed to a mountain slope while the fall-prevention network is pressed, and the bridge plate and the wire rope are connected by four springs. However, when the load is concentrated on the ring of the spring and one of the spring rings is dropped, tensile force acting on the binding plate becomes unbalanced and the binding plate is not fixed. there was.

In addition, Korean Patent No. 10-101390176 discloses a " buffer-type fastening device for a wire rope for a fall-prevention network ", which can effectively absorb shock applied to a fall-prevention network using spring and cruciform binding pieces. Concretely, the first and second buffer binding pieces of the cruciform binding bands are crossed with each other by "X", and the binding pieces are connected to each other through the tension spring. This is a structure that keeps the tension of the wire rope and prevents the rockfall preventing network from hitting the mountain slope. However, when one of the pair of opposing wire ropes is disconnected or the spring hook is removed, There was a limit in that the fixing device itself could not function properly.

Even if the spring connecting the wire rope to the binding wire is disconnected due to the collision with the large rockfall, the safety of preventing the accident of the falling rock to the road is prevented by the double connection structure of the auxiliary ropes so that the connection between the wire ropes can be continuously maintained And to provide improved rockfall prevention facilities. The present invention is not limited to the above-described technical problems and other technical problems can be derived from the following description.

The anti-rockfall facility according to the present invention includes a rockfall prevention network covering a rockfall area of a mountain slope adjacent to the road; A plurality of binding members each formed in a cross shape having both ends in the longitudinal direction and both ends in the transverse direction and arranged in a lattice point structure of a tetragonal lattice on the rockfall prevention network; A plurality of tension springs arranged in four longitudinally and transversely opposite ends of each of the binding ports for each of the binding ports so as to be engaged with both longitudinal ends and both lateral ends of the binding ports; Wherein each of the plurality of binding members is disposed between two binding members adjacent to each other in the longitudinal direction of the plurality of binding members so that one end thereof is engaged with a tension spring longitudinally coupled to one binding member, A plurality of longitudinal ropes engaging longitudinally coupled tension springs; Each of the plurality of binding members is disposed between two binding members adjacent to each other in the transverse direction of the plurality of binding members and is engaged with a tension spring whose one end is laterally coupled to one binding member and the other end is engaged with another binding member A plurality of transverse ropes engaging a transversely coupled tension spring; Each of which is formed in a shape that can be worn on the end of each of the longitudinal ropes or each of the longitudinal ropes, so as to surround the end of each longitudinal rope or each of the longitudinal ropes, A plurality of adapters to be fastened; A plurality of longitudinal auxiliary ropes each of which is overlapped with the two longitudinal ropes between two longitudinal ropes coupled to tension springs at both longitudinal ends of the respective binding means; A plurality of transverse rope ropes, each of which is disposed to overlap with the two transverse ropes between two transverse ropes joined to tension springs at both lateral ends of the respective binding means; Each of which is formed in a shape that can be laid on the end of each of the auxiliary ropes or each of the transverse coarse ropes so as to surround the ends of the respective auxiliary rope or each of the transverse coarse ropes, A plurality of caps fastened to opposite ends of the rope; And a first sliding hole formed to have a size smaller than the diameter of the adapter and surrounding a longitudinal rope or a transverse rope portion at a position spaced apart from each adapter, and a second sliding hole formed to have a size smaller than the diameter of each of the caps, And a plurality of joints having a second sliding hole surrounding the longitudinal auxiliary rope or the transverse rope portion in the spaced apart position, wherein one of the plurality of tension springs Wherein one of the long ropes or the transverse rope is slidably moved in the first sliding hole until the one end of the long rope or the one end of the transverse rope is caught by the first sliding hole, And at the same time, the cap of one end of the one of the longitudinal auxiliary ropes or the lateral rope is inserted into the second sliding hole The one of the longitudinal auxiliary ropes or the transverse rope is slidably moved in the second sliding hole until it is caught.

Wherein each of the joints comprises a bracket having a bottom plate and a pair of side plates and a bending plate having a cross-sectional shape of a " [" And a cover that covers the grooves of the two side plates of the bracket in a state where the longitudinal auxiliary rope or the side portion of the side rope of the bracket is spaced apart from the respective caps in the groove of the two side plates, May be formed by a space between the grooves of the two side plates of the bracket and the cover.

Wherein each of the joints has two ends of a bolt in a state in which a longitudinal rope portion or a transverse rope portion at a position spaced apart from each of the adapters is fitted in an inner side of a semicircular portion and two through holes of a lower plate of the bracket, A U-shaped bolt projecting from the cover after passing through the U-shaped bolt; And a nut that is positioned on the cover and is engaged with both ends of a U-shaped bolt projecting from the cover, thereby coupling the bracket to the cover, wherein the first sliding hole is formed by a lower plate of the bracket, As shown in FIG.

The anti-rockfall facility further includes a plurality of state identification plates arranged on the intersection of the longitudinal auxiliary rope and the lateral rope crossing each other on each of the binding bars and fixed by being joined to the longitudinal rope and the lateral rope of the intersection point And when each of the longitudinal and transverse ropes intersecting on the respective binding gates is slid, the gaps between the longitudinal ropes at the crossing points or the gaps between the transverse ropes spread, The coupling between the rope and the lap joint rope can be released and released from the intersection point.

Wherein each of the state identification plates has two through holes and both ends thereof are coupled to two longitudinal ropes passing through the two through holes and coupled to tension springs at both longitudinal ends of the respective binding rings, A plurality of longitudinal lines connecting the identification plate to a longitudinal rope of the intersection; And a plurality of transverse ropes each bounded by two transverse ropes, each transverse rope being bound to two transverse ropes coupled to tension springs at transversely opposite ends of each of the bite holes, Wherein when one of the longitudinal rope and the lateral rope is slid and moved away from each of the binding ports, the longitudinal fixed line or the lateral fixed line is pulled in an elongated state, .

Both ends of the longitudinal auxiliary rope are connected to two longitudinal ropes connected to the coupling rods and the opposite ends of the roving rope are connected to two transverse ropes connected to the coupling rods in the transverse direction so that the hooks of the tension springs are removed from the coupling rods It is possible to maintain the connection of the entire anti-rocking facility by grabbing both longitudinal ropes and two lateral ropes. With this double connection structure, it is possible to prevent or delay the accident that the rock covered by the rockfall prevention net supported by the longitudinal rope and the lateral rope penetrates the net and pours into the road by maintaining the connection state of the longitudinal rope or the lateral rope, The safety of the rockfall prevention facility can be greatly improved.

In addition, by adjusting the degree of tightening of the nut with respect to the U-shaped bolt, the gap between the groove and cover of the two side plates of the bracket and the gap between the lower plate of the bracket and the U-shaped bolt can be adjusted at once. Because of this adjustable structure, it is possible to realize the first sliding hole and the second sliding hole of the optimum size to be able to slide the wire rope and the auxiliary rope, so that the reliability of the sliding movement of the wire rope and the auxiliary rope is secured .

It is also possible to position the state discrimination plate on each linkage where the longitudinal auxiliary rope and the lateral linkage ropes cross each other and to allow the state identification plate to be disengaged when either the longitudinal rope or the transverse rope moves away from the respective linkage, A safety diagnosis function can be provided. Due to this safety diagnosis function, the manager can clearly determine whether or not the tension spring connected to each binding orifice is detached or not by the presence or absence of the state-of-the-art type plate.

In addition, when the tension spring and the transverse rope are separated from each other due to the fall of the tension spring, the longitudinal and transverse fixed lines are connected to each other through the two through holes of the state identification plate. And the two through holes of the state identification plate are broken. As described above, the reliability of the safety diagnosis function can be improved by the connection structure in which the state identification plate can be reliably detached when the tension spring is detached.

1 is a perspective view of an anti-rockfall facility according to an embodiment of the present invention.
2 is an exploded view of a joint of an anti-rocking facility according to an embodiment of the present invention.
3 is a perspective view of a rockfall prevention facility according to another embodiment of the present invention.
4 is a rear perspective view and a use state view of a rockfall preventing facility according to another embodiment of the present invention.
5 is a state of use in which another embodiment of the present invention is installed on a mountain slope.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below are capable of absorbing an external shock by primarily providing a shock absorbing capability of the rockfall preventing network and a dual connection structure in which the wire rope is not detached even if the spring connecting the wire rope and the binding hole is dropped. The present invention relates to an anti-rocking facility having a safety diagnosis function that allows easy visual identification of whether or not a connection state, such as a drop of a spring, is abnormal. Hereinafter, an anti-rockfall facility having a double wire rope structure having a safety diagnosis function for solving the existing problems according to embodiments of the present invention will be briefly described as a 'rockfall prevention facility'.

1 is a perspective view of an anti-rockfall facility according to an embodiment of the present invention. 1, an anti-rockfall facility according to an embodiment of the present invention includes a rockfall preventing network N, a plurality of binding members 30, a plurality of tension springs 20, a plurality of long ropes 10a, And is composed of a transverse rope 10b, a plurality of adapters 11, a plurality of longitudinal auxiliary ropes 40a, a plurality of transverse ropes 40b, a plurality of caps 41 and a plurality of joints 60. [ The anti-rockfall facility according to the present embodiment may further include additional components other than the above-described components. Other embodiments described below may further include other additional components.

The rockfall preventing net (N) is a net that covers the mountain slope adjacent to the roadside, and is fixedly installed in close contact with a mountain slope such as a cut-off slope to prevent rocks and the like from falling off the mountain slope. The fall-prevention network (N) is mainly composed of a poly-vinyl chloride coated wire mesh, and is installed between a plurality of wire ropes (10) stretched in a lattice structure and stretched in its entirety and tightly fixed to a mountain slope do.

Each of the plurality of binding ports 30 is formed in a cross shape having both ends in the longitudinal direction and both ends in the transverse direction and is arranged in a lattice point structure of a tetragonal lattice on the falling-stone prevention net N. As shown in FIG. 1, each binding port 30 includes cross brackets 31 and 32 in the form of a cross '+' having both ends in the longitudinal direction and both ends in the transverse direction. And an anchor bolt 33 penetrating therethrough is fastened. The anchor bolts 33 are press-fitted into the inclined surfaces to fix the positions of the cross brackets 31 and 32. In other words, the binding port 30 has a first bracket 31, a transversely sectioned second bracket 32, a first bracket 31 and a second bracket 32, Anchor bolts 33 for fixing to the mountain slopes and four annular bolts 34 and anchor bolts 33 which are fixed to the four flanges of the cross brackets 31 and 32 so that the hooks of the tension spring 20 can be caught, And a nut 35 for fixing the collar bolts 34 to the first bracket 31 and the second bracket 32. [

The first bracket 31 of the binding port 30 is composed of a square plate-like main portion and a pair of flanges extending vertically upward from the side edges of the main portion vertically, '' Has a shape rotated by 90 ° in the counterclockwise direction. Similarly to the first bracket 31, the second bracket 32 is composed of a square plate-like main portion and a pair of flanges extending vertically upward from the corners of the main portion vertically, '[' 'Has a shape rotated by 90 ° in the counterclockwise direction with respect to the installed floor. The first bracket 31 and the second bracket 32 are perpendicular to each other and are in close contact with each other, so that a bracket of a cross '+' shape can be formed. A through hole is formed in each of the center of intersection of the first bracket 31 and the second bracket 32 and the both flanges.

One side of the anchor bolt 33 of the binding means 30 is formed in the form of a bolt and protrudes upward through the through hole at the intersection of the first bracket 31 and the second bracket 32, And is press-fitted into the mountain slope. The nut 35 is fastened to the bolt portion of the anchor bolt 33 protruding upward through the through hole at the intersection point of the first bracket 31 and the second bracket 32 so that the anchor bolt 33 is fastened to the first bracket 31. [ (31) and the second bracket (32). Since the first bracket 31 and the second bracket 32 are fixed to the mountain slopes in a structure rotatable along the direction of the wire rope 10 connected to the first and second brackets 31 and 32, 10 can not be arranged in a perfect lattice structure.

Each of the four annular bolts 34 is formed in a bolt shape on one side thereof so as to protrude inward through both flanges of the first bracket 31 and the through holes of both flanges of the second bracket 32, And is protruded outward from both side flanges of the first bracket 31 and both flanges of the second bracket 32. [ Nuts 35 are fastened to the bolt portions of the four annular bolts 34 protruding inwardly through the through holes of the flanges on both sides of the first bracket 31 and the flanges on both sides of the second bracket 32, The collar bolts 34 can be fixed to the first bracket 31 and the second bracket 32. [ Since the flanges on both sides of the first bracket 31 and the flanges on both sides of the second bracket 32 can be bent to some extent in accordance with the external force, due to the shape of the binding opening 30 having the flange, But can also function as a buffering function in the binding means 30 itself.

The plurality of tension springs 20 are arranged in four longitudinally opposite ends of the binding means 30 and at both ends in the transverse direction for each binding means 30, And is engaged with both ends of the direction. As shown in FIG. 1, two tensile springs 20 are provided in the longitudinal direction, with a structure in which a hook at the end of a tensile spring 20 is engaged at each end of a coupling pin 30 of '+' And two tension springs are installed in the lateral direction. The tension spring 20 elastically applies the rigid wire rope 10 while connecting the wire rope 10 and the coupling hole 30 to each other, thereby buffering external shocks applied to the entire rockfall prevention network.

The tension spring 20 is formed at both ends thereof in the form of hooks and has a restoring force proportional to a tensile length up to a predetermined stress. One of the hooks of the tension spring 20 is coupled to the distal end of the wire rope 10 and the other hook is hooked to the hook bolt 34 of the binding port 30. [ The tension spring 20 has a problem that the hook of the tension spring 20 is pulled off when a certain impact or load is applied. The tensile spring 20 is a member that connects the binding port 30 and the wire rope 10, and when the hook of the tension spring 20 is detached, the rock tears the anti-rocking net and pours down into the road. In the example, as described below, a pair of wire ropes 10 connected to both sides of the binding opening 30 is connected to the auxiliary rope 40 in order to prevent such a large accident.

The plurality of wire ropes (10) is composed of a plurality of longitudinal ropes (10a) arranged in the longitudinal direction and a transverse rope (10b) arranged in the lateral direction. Here, the plurality of long ropes 10a are disposed between the two binding ports 30 adjacent to each other in the longitudinal direction among the plurality of binding ports 30, and one end is connected to one of the two binding ports 30 And the other end is engaged with a tension spring 20 coupled to the other coupling spindle 30 in the longitudinal direction. Each of the plurality of transverse ropes 10b is disposed between two binding members 30 adjacent to each other in the transverse direction among the plurality of binding members 30 and one end of the two lateral binding members 30 is connected to one of the two binding members 30 And the other end is engaged with a tension spring 20 which is laterally coupled to the other coupling hole 30. The other end of the tension spring 20 is engaged with the tension spring 20,

At both ends of each wire rope 10, an adapter 11, which can be put on the end of each wire rope 10, is fastened with a structure wrapping the end of each wire rope 10. Each of the plurality of adapters 11 is formed in such a shape as to be able to be worn on the end of each longitudinal rope 10a or each lateral rope 10b so that each longitudinal rope 10a or each lateral rope 10b And is fastened to both ends of each longitudinal rope 10a and each lateral rope 10b. The other end of the wire rope 10 may be bolted to each of the bolt-type ends of the wire rope 10, and the other end of the wire rope 10 may be engaged with one end of each tension spring 30. With this adapter 11, both ends of each wire rope 10 can be engaged with the two tension springs 20.

The plurality of auxiliary ropes 40 are composed of a plurality of longitudinal auxiliary ropes 40a arranged in the longitudinal direction and a plurality of transverse stabilizing ropes 40a arranged in the lateral direction. Each of the plurality of longitudinal auxiliary ropes 40a has two longitudinal ropes 10a and 10b between two longitudinal ropes 10a coupled to the tension springs 20 at both longitudinal ends of each of the longitudinal coupling rods 30, Respectively. Each of the plurality of transverse ropes 40a has two transverse ropes 10b and two transverse ropes 10b between two transverse ropes 10b coupled to tensile springs 20 at transversely opposite ends of the respective coupling means 30. [ Respectively.

Each of the auxiliary ropes 40 is a rope connected at the same time to a pair of wire ropes 10 symmetrically spaced apart from each other around the binding port 30 to assist in connection of the pair of wire ropes 10, The connection state of the wire ropes 10 can be maintained even when the hook 20 of the spring 20 is removed, thereby preventing breakage of the fall-preventing network or delaying it for a predetermined period of time.

At both ends of each of the auxiliary ropes 40, a cap 41 that can be put on the end of each auxiliary rope 40 is fastened with a structure wrapping the end of each auxiliary rope 40. Each of the plurality of caps 41 is formed so as to be capable of being worn on the end of each kind of auxiliary rope 40a or each of the transverse adjustment ropes 40b so that each kind of auxiliary rope 40a or each of the transverse adjustment ropes 40b, And is fastened to both ends of each kind auxiliary rope 40a and each of the transverse ropes 40b. The longitudinal auxiliary rope 40a and the transverse rope 40b of each auxiliary rope 40 are provided in a straight line on the binding port 30, Both ends of each auxiliary rope 40 are tightly coupled to the pair of wire ropes 10. Due to this double connection structure, it is possible to prevent or delay the accident that the rock covered by the rockfall prevention net supported by the longitudinal rope and the lateral rope penetrates the net and pours into the road by maintaining the connection state of the longitudinal rope or the lateral rope, The safety of the rockfall prevention facility can be greatly improved.

2 is an exploded view of a joint of an anti-rocking facility according to an embodiment of the present invention. 2, each joint 60 is composed of a bracket 61, a cover 62, a U-shaped bolt 63, and a nut 64, The first sliding hole A surrounding the longitudinal rope 10a or the transverse rope 10b at a position spaced apart from each adapter 11 and the diameter of each cap 41 And a second sliding hole B which is formed in a small size and surrounds the longitudinally auxiliary rope 40a or the side portion of the transverse rope 40b at a position spaced apart from each cap 41. [

The bracket 61 of each joint 60 is a bending plate of a cross-section of "[" type having one lower plate and two side plates, and one groove is formed in each of the two side plates. In addition, two through holes are formed in one lower plate of the bracket 61. That is, the lower plate of the bracket 61 is formed in the shape of a rectangular plate, and the two side plates are formed in the shape of a rectangular plate extending from both ends of the lower plate at right angles. Each of the two side plates of the bracket 61 is formed with a groove into which the auxiliary rope 40 can be seated. The grooves formed in the two side plates of the bracket 61 are slightly larger than the diameter of the auxiliary rope 10 and smaller than the diameter of the cap 41 so that the auxiliary rope 40 can enter the inside thereof. The auxiliary rope 40 can be slidably moved in the second sliding hole B until the cap 41 is caught by the bracket 61 of the joint 60. [

The cover 62 of each joint 60 is a rectangular flat plate having two through holes formed therein so that the auxiliary rope portion at a position spaced apart from each cap 41 is inserted into the groove of the two side plates of the bracket 61, (61). The second sliding hole B is formed by a space between the grooves of the two side plates of the bracket 61 and the cover 62 and an auxiliary rope portion at a position spaced apart from each cap 41 is inserted therein . The rigid second sliding hole B which is not damaged by the momentary movement of the auxiliary rope 60 by the bracket 61 and the cover 62 of the joint 60 can be realized.

The U-shaped bolt 63 of each joint 60 is formed in a "U" shape having both ends in the form of a bolt, and a wire rope portion at a position spaced apart from each adapter 11 is fitted in the inner side of the semi- Both ends of the mold are protruded from the cover 62 after passing through the two through holes of the lower plate of the bracket 61 and the two through holes of the cover 62 in order. The width between the both ends of the U-shaped bolt 63 is slightly larger than the diameter of the wire rope 10 and smaller than the diameter of the adapter 11 so that the wire rope 10 can enter the inside thereof. Therefore, the wire rope 10 can be slidably moved in the first sliding hole A until the adapter 11 is caught by the U-shaped bolt 63 of the joint 60.

The nut 64 of each joint 60 is engaged with both ends of the U-shaped bolt 63 protruding from the cover 62 on the cover 62 so as to engage the bracket 61 with the cover 62 . The first sliding hole A is formed by a space between the lower plate of the bracket 61 and the U-shaped bolt 63, and a wire rope portion at a position spaced apart from each adapter 11 is inserted therein. By embodying the first sliding hole A and the second sliding hole B of the joint 60 corresponding to the diameters of the wire rope 10 and the auxiliary rope 40 as described above, The auxiliary rope 40 can be smoothly slid within the sliding hole A and the auxiliary rope 40 can be smoothly slidably moved in the second sliding hole B. [ In addition, since the spacing of the sliding holes can be changed by fastening the projecting portion of the U-shaped bolt 63 with the nut 64, it is possible to cope with ropes of various thicknesses.

As described above, when a certain tension spring 20 is disengaged, the adapter 11 engaged with the adapter 11 is engaged with the first sliding hole A between the lower plate of the bracket 61 and the U-shaped bolt 63 The wire rope 10 is slid and the adapter 11 engaged with the tension spring 20 is engaged with the second sliding hole B between the groove of the two side plates of the bracket 61 and the cover 62 The auxiliary rope 40 can be slidably moved. Each of the wire rope 10 and each auxiliary rope 40 can slide in the horizontal direction while its adapter 11 and its cap 41 are caught by the joint 60, Can be limited. The two wire ropes 10 adjacent to each other can be connected to each other through the auxiliary rope 20 even in the situation where the tension spring 20 is pulled out of the binding opening 30 by the double connection structure.

Further, since the wire rope 10 and the auxiliary rope 40 are formed by twisting multiple strands several times, the diameter of each wire is not constant. The tightening degree of the nut 64 with respect to the U-shaped bolt 63 is adjusted so that the distance between the grooves of the two side plates of the bracket 61 and the cover 62 and the distance between the lower plate of the bracket 61 and the U- The interval between the bolts 63 can be adjusted at one time. Accordingly, the first sliding hole A and the second sliding hole B of the optimum size capable of sliding movement of the wire rope 10 and the auxiliary rope 40 can be formed, The reliability of the sliding movement of the rope 10 and the auxiliary rope 40 can be ensured, thereby providing an anti-rocking facility with greatly improved safety.

That is, in the present embodiment, when any one of the tensile springs 20 is pulled out of the binding opening 30 due to an impact applied to any one of the plurality of tension springs 20 caught by the binding opening 30, One of the wire ropes 10 is slidingly moved in the first sliding hole A until the adapter 11 at one end of one wire rope 10 is caught in the first sliding hole A, One of the auxiliary ropes 40 is slid and moved in the second sliding hole B until the cap 41 at one end of the auxiliary rope 40 of the auxiliary rope 40 is caught by the second sliding hole B.

Even if the tensile spring 20 is disengaged and the connection between the wire rope 10 and the coupling aperture 30 is cut off due to the structure in which the auxiliary rope 40 is installed in this way, A pair of wire ropes 10 are continuously connected and the connection between the wire ropes 10 can be maintained. Therefore, the connection state of the wire rope 10 can be maintained even in the emergency in which the tension spring 20 comes off, so that the rock supported by the wire rope 10 can be prevented or delayed from being poured into the road through the network .

FIG. 3 is a perspective view of a rockfall preventing facility according to another embodiment of the present invention, and FIG. 4 is a rear perspective view and a use state view of a rockfall preventing facility according to another embodiment of the present invention. 3 and 4, an anti-rockfall facility according to another embodiment of the present invention includes a rockfall preventing network N, a plurality of binding members 30, a plurality of tension springs 20, a plurality of long ropes 10a, A plurality of longitudinal ropes 10b, a plurality of adapters 11, a plurality of longitudinal auxiliary ropes 40a, a plurality of transverse ropes 40b, a plurality of caps 41, a plurality of joints 60, And a state identification plate 50. The wire rope 10, the tension spring 20, the coupling 30, the auxiliary rope 40, and the joint 60 are the same as those shown in Figs. 1 and 2, 1 and the description of the embodiment shown in FIG. 2 will be omitted. The state identification plate 50 will be mainly described below.

The plurality of state identification plates 50 are disposed on the intersections of the longitudinal auxiliary ropes 40a and the transverse ropes 40b which intersect on the respective coupling means 30 and are disposed at the intersection between the longitudinal rope 10a and the transverse rope 40a. And fixed to the rope 10b. In this case, when each of the longitudinal rope 10a and the lateral rope 10b intersecting on the binding joints 30 is slidably moved, the state identification plates 50 are spaced apart from each other by a distance Or the transverse ropes 10b are spread, the binding between the longitudinal auxiliary rope 40a and the transverse rope 40b is released and separated from the intersection point. Due to this safety diagnosis function, the manager can clearly determine whether or not the tension spring connected to each binding orifice is detached or not by the presence or absence of the state-of-the-art type plate.

 The fixed line 51 means the longitudinal fixed line 51a and the lateral fixed line 51b and each fixed line 51 is thinner than the wire rope 10 and the auxiliary rope 40 but stronger than the state discrimination plate 50 .

Specifically, the plurality of state identification plates 50 are disposed on the intersections of the longitudinal auxiliary ropes 40a and the transverse ropes 40b, each of which crosses over each of the binding members 30, and have two through-holes . The upper surface of the state discrimination plate 50 may be coated with a fluorescent material, a reflective material, or a fluorescent paper or a reflection paper so as to be distinguishable from a distance, and the shape is not limited to a circular disk as shown in FIG. That is, it can be deformed into another shape that can be identified or the auxiliary rope 40 can be coupled to, and can be made of a synthetic resin material. The state identification plate 50 is separated from the tension spring 30 due to the fall of the tension spring 30. The administrator of the anti-rocking facility can easily check whether the state of the wire rope 10 is abnormal It is possible to provide a safety diagnosis function which can be checked. The state discrimination board 50 is constructed by intersecting the longitudinal auxiliary rope 40a and the transverse rope 40b using the longitudinal fixing line 51a connected to the longitudinal rope 10a and the transverse fixing line 51b connected to the lateral rope 10b. Lt; / RTI >

The plurality of longitudinal fixed lines 51a are connected to the tension springs 20 at both ends of the longitudinal direction of each coupling hole 30 through two through holes of the state discrimination plate 50, (10a) to bind each state identification plate (50) to the longitudinal rope (10a) at the intersection point. That is, each of the longitudinal fixed lines 51a is disposed between the two longitudinal ropes 10a coupled to the tension springs 20 at both longitudinal ends of each of the longitudinal coupling bails 30, And the other end is bound to the other long rope 10a and passes through the two through holes of the state identification plate 50. [

The plurality of transverse fixing lines 51b are connected to two transverse ropes 10b that are connected to the tension springs 20 at both ends of the transverse direction of the binding members 30 through both of the through holes at their both ends So that each state identification plate 50 is bound to the transverse rope 10b at the crossing point. That is, each of the plurality of lateral fixing lines 51b is disposed between the two lateral ropes 10b coupled to the tension springs 20 at both lateral ends of the binding joints 30, 10b and the other end is bound to the other transverse rope 10b and passes through the two through holes of the state identification plate 50. [

Each of the longitudinal fixed lines 51a is connected to the end of two adjacent longitudinal ropes 10a around the respective coupling ports 30 and each lateral fixing line 51b is connected to two adjacent lateral ropes (10b). The fixed line 51 is connected to each wire rope 10 through two through holes formed in the state identification plate 50 to connect the state discrimination plate 50 to the longitudinal auxiliary rope 40a and the transverse rope 40b And fix it on the intersection point. Specifically, as shown in FIG. 3, the longitudinal fixed line 51a is connected to two longitudinal ropes 10a through two through-holes, and the lateral fixed line 51b passes through two through- Are connected to each other. The longitudinal fixed line 51a and the lateral fixed line 51b may pass through the two through holes of the state discrimination plate 50 and intersect between the two through holes as shown in Figure 4 (a).

When either the longitudinal rope 10a or the transverse rope 10b is moved away from the binding port 30 when the tension spring 20 is detached from the binding port 30, the longitudinal fixed line 51a or the lateral fixing line 51b So that the two through holes of each state identifying plate 50 are broken. That is, when the tension spring 20 is removed, the fixed line 50 is pulled tightly to break the state identification plate 50 and to be released to the outside. The longitudinal rope 10a or the transverse rope 10b is positioned so as to allow the adapter 11 to move in the direction of the arrow U of the joint 60 when the hooks of one of the tension springs 20 connected to the binding opening 30 are pulled out "Until it is caught by the bolt. The longitudinal fixed line 51a or the lateral fixed line 51b connected to the longitudinal rope 10a or the lateral rope 10b is also tautly stretched linearly to break the space between the two through holes of the state identification plate 50, 50 are separated from the intersection of the longitudinal auxiliary rope 40a and the lateral rope 40b. Any one of the longitudinal fixed line 51a and the lateral fixed line 51b is stretched in a state of being stretched to break the state discriminating plate 50 by applying a shearing force between the two through holes so that the state discriminating plate 50 can reliably come off from the intersection point . That is, since the state identification plate 50 can be reliably detached when the tension spring 20 comes off, the reliability of the safety diagnosis function can be improved.

As shown in Figs. 3-4, the longitudinal fixed line 51a and the lateral fixed line 51b may pass from the upper surface to the lower surface after passing through the through hole of the state identification plate 50 from the lower surface to the upper surface, From the lower surface to the upper surface. In both connection structures, each state identification plate 50 is formed in a state in which two of the state identification plates 50 are connected to each other in the case where one of the longitudinal fixed line 51a and the lateral fixed line 51b is tightly twisted on each of the coupling members 30 The portion between the through holes is removed.

Fig. 5 is a state of use in which another embodiment of Fig. 2 is installed on a mountain slope; Fig. As shown in FIG. 5, the rockfall preventing net N covers the mountain slope of the road side where the rockfall is expected to be entirely covered, and the plurality of wire ropes 10 are connected to each other over the rockfall preventing net to closely contact the rockfall preventing net N and the mountain slope. At the point where the extension lines of the wire rope 10 intersect each other, a binding port for connecting the four wire ropes 10 in a cross (+) form via four tension springs is located, and the anchor bolt of the binding port And the binding port is fixed.

In the embodiment described above, four tension springs hooked to the binding joints are used to primarily absorb the impact caused by the collision with the fallen stones, It is possible to reduce the breakage of the anti-rockfall preventing network. Even if one of the four tension springs hooked to the respective fasteners is dropped off on the basis of the double connection structure in which the pair of wire ropes 10 facing each of the fasteners is connected to the auxiliary rope pro, The connection state of the wire rope 10 can be maintained. As described above, in the embodiment described above, since the connection of the plurality of wire ropes 10 is released, the rock falls into the road, thereby preventing the breakage of the road facilities and the automobile accident by preventing or delaying the auxiliary ropes. Can be improved.

In another embodiment shown in FIG. 5, a safety diagnosis function may be added in one embodiment, so that a safety diagnosis can be made only by the presence or absence of the state identification plate 50. That is, another embodiment adds the state discrimination plate 50 to enable visual diagnosis of the safety diagnosis more easily by the naked eye in the invention of one embodiment. Specifically, in order to facilitate the safety diagnosis, the longitudinal auxiliary rope and the transverse rope cross each other, and the state identification plate 50 is disposed at the intersection of the longitudinal auxiliary rope and the transverse rope. The wire rope 10 with the tensile spring removed is slid until the adapter is engaged with the joint so that a fixed line connected to the wire rope 10 breaks the portion between the two through holes of the state identification plate 50, Is released and the state identification plate 50 is released. It is possible to provide a safety diagnosis function that allows the administrator to visually check whether the state of the wire rope connection is abnormal by confirming whether or not the state identification plate 50 of the rockfall preventing facility is present as in the use state diagram of FIG.

The present invention has been described above with reference to preferred embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

10: Wire rope 10a:
10b: transverse rope 11: adapter
20: Tension spring
30: Bonding District
40: auxiliary rope 40a: longitudinal auxiliary rope
40b: Lap joint rope 41: Cap
50: state identification plate 51: fixed line
51a: longitudinal fixed line 52b: lateral fixed line
60: joint 61: bracket
62: Cover 63: U-shaped bolt
64: nut

Claims (5)

A rockfall protection net covering the fall area of a mountain slope adjacent to the road;
A plurality of binding members each formed in a cross shape having both ends in the longitudinal direction and both ends in the transverse direction and arranged in a lattice point structure of a tetragonal lattice on the rockfall prevention network;
A plurality of tension springs arranged in four longitudinally and transversely opposite ends of each of the binding ports for each of the binding ports so as to be engaged with both longitudinal ends and both lateral ends of the binding ports;
Wherein each of the plurality of binding members is disposed between two binding members adjacent to each other in the longitudinal direction of the plurality of binding members so that one end thereof is engaged with a tension spring longitudinally coupled to one binding member, A plurality of longitudinal ropes engaging longitudinally coupled tension springs;
Each of the plurality of binding members is disposed between two binding members adjacent to each other in the transverse direction of the plurality of binding members and is engaged with a tension spring whose one end is laterally coupled to one binding member and the other end is engaged with another binding member A plurality of transverse ropes engaging a transversely coupled tension spring;
Each of which is formed in a shape that can be worn on the end of each of the longitudinal ropes or each of the longitudinal ropes, so as to surround the end of each longitudinal rope or each of the longitudinal ropes, A plurality of adapters to be fastened;
A plurality of longitudinal auxiliary ropes each of which is overlapped with the two longitudinal ropes between two longitudinal ropes coupled to tension springs at both longitudinal ends of the respective binding means;
A plurality of transverse rope ropes, each of which is disposed to overlap with the two transverse ropes between two transverse ropes joined to tension springs at both lateral ends of the respective binding means;
Each of which is formed in a shape that can be laid on the end of each of the auxiliary ropes or each of the transverse coarse ropes so as to surround the ends of the respective auxiliary rope or each of the transverse coarse ropes, A plurality of caps fastened to opposite ends of the rope; And
Each having a size smaller than a diameter of the adapter and having a first sliding hole surrounding a longitudinal rope or a transverse rope portion spaced apart from the adapters and a second sliding hole formed to have a size smaller than a diameter of each of the caps, And a second sliding hole surrounding the longitudinal auxiliary rope or the transverse rope portion in the second position,
When one of the tensile springs is detached from the coupling hole due to an impact applied to any one of the plurality of tension springs, one of the long ropes or one end of the transverse rope is inserted into the first sliding hole Wherein one of the longitudinal ropes or the transverse rope is slid in the first sliding hole until the one of the longitudinal auxiliary ropes or the transverse rope is caught by the second sliding hole, Wherein any one of the longitudinal auxiliary ropes or the transverse rope is slidably moved in the second sliding hole. The method according to claim 1,
Each of the above-
A bracket having a bottom plate and two side plates and having a groove formed in each of the two side plates by a bent plate having a cross-sectional shape of a "[" And
And a cover which covers the grooves of the two side plates of the bracket in a state in which the longitudinal auxiliary rope or the transverse rope portion at a position spaced apart from the respective caps is fitted in the groove of the two side plates of the bracket,
And the second sliding hole is formed by a space between the grooves of the two side plates of the bracket and the cover. 3. The method of claim 2,
Each of the above-
In the state where the longitudinal rope portion or the transverse rope portion at the position spaced apart from the respective adapters is fitted to the inner side of the semicircular portion, both ends of the bolt type are passed through the two through holes of the lower plate of the bracket and the two through holes of the cover A U-shaped bolt projecting from the cover afterwards; And
Further comprising: a nut positioned on the cover and coupled to both ends of a U-shaped bolt projecting from the cover to engage the bracket with the cover,
Wherein the first sliding hole is formed by a space between the lower plate of the bracket and the U-shaped bolt. The method according to claim 1,
Further comprising a plurality of state identification plates which are arranged on the intersection of the longitudinal auxiliary rope and the lateral joint rope, each of which crosses on each of the coupling means, and which are fixed by being joined to the longitudinal rope and the lateral rope of the intersection,
Wherein each of the state identification plates has a shape in which the distance between the longitudinal ropes at the intersection points or the distance between the transverse ropes is enlarged when one of the longitudinal ropes and the lateral ropes crossing each other on the binding rings is slid, Wherein the coupling with the lap joint rope is released and separated from the intersection point. 5. The method of claim 4,
In the state identification plates, two through holes are formed,
Each end of each of which is coupled to two longitudinal ropes coupled to tension springs at both longitudinal ends of the respective bite holes through the two through holes to connect the respective state identification plates to the longitudinal rope at the intersection point Bongsoo Jeongseon; And
Each side of which is coupled to two transverse ropes which are passed through the two through holes and are coupled to tension springs at both ends of the transverse direction of the binding means so as to bind the respective state discriminating plates to the transverse rope of the intersection point. Comprising a fixed line,
Wherein when one of the longitudinal rope and the lateral rope is slidably moved away from the respective binding port, the longitudinal fixed line or the lateral fixed line is pulled tightly to break the space between the two through holes of the respective state identifying plates Rockfall prevention facility.

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