KR101003520B1 - Apparatus for preventing from falling rocks onto the road - Google Patents

Abstract

PURPOSE: A falling stone prevention fence with an overturning prevention function is provided to prevent the overturning of the posts, since each post bidirectionally disperses and accepts the load of falling stones. CONSTITUTION: A falling stone prevention fence(100) with an overturning prevention function comprises a connection unit, a load dispersion unit, a hinge unit, and a falling stone support unit. The connection unit comprises multiple brackets. The multiple brackets are vertically projected to both sides each post(120) at regular intervals. The load dispersion unit is placed to correspond to each bracket of the connection unit. The load dispersion unit comprises multiple rotary levers. The multiple rotary levers are placed on both sides of the post. The falling stone support unit comprises multiple steel wires(150) and a pressure plate.

Description

Falling prevention measures that strengthened fall prevention function {APPARATUS FOR PREVENTING FROM FALLING ROCKS ONTO THE ROAD}

The present invention relates to a rockfall prevention measure that prevents heavy objects such as falling rocks and lumps (hereinafter referred to simply as "falling rocks") falling through a slope adjacent to a road to fall on the road. By distributing and receiving the load acting on both directions effectively, it prevents propagation of struts toward the center of load that pushes the strut, and prevents the propagation of the strut first, and utilizes the load of the rockfall applied to the pressure plate installed on the back of each strut. Therefore, it is related to the fall prevention measures which have strengthened the fall prevention function improved to retard the fall of the landlord as a whole and to greatly enhance the safety by secondarily resisting the force to fall the landlord to the road side by maintaining the back of the land support firmly on the ground.

In general, rockfall prevention measures are essential safety facilities to prevent the phenomenon of falling rocks on the road and causing collision of vehicles after constructing the road mainly in mountainous areas.

Such a conventional rockfall prevention measure (1) is typically a retaining wall 10 is constructed at the bottom end of the slope 5 adjacent to the road, as shown in Figures 1a and 2b, a predetermined interval on the retaining wall (10) After the strut 20 is installed, the mesh-shaped blocking net 30 is mounted in the interval between the struts 20.

And when the heavyweight rockfall 40 falls on such a strut 20, the steel wire 50 in the transverse direction to cross between the strut 20 and the strut 20 in order to reinforce the blocking net 30. It is fixed to each strut 20 through the clamp 22, such a steel wire 50 is mounted a plurality while maintaining a constant interval in the vertical direction of the strut 20.

In addition, the blocking net 30 is made of a metal mesh of assuming that the falling rock 40 falling from the slope 5 is a considerable weight, and is made to have a suitable height and width in consideration of the installation space.

Therefore, the conventional rockfall prevention measures (1) is to prevent the falling rock 40 falling from the slope 5 is caught by the strut 20, the steel wire 50 and the blocking net 30 to fall to the road side.

However, such a conventional fall prevention measure (1) is a simple straight post pillar 20 is stable even from the primary impact, when a large amount of rock and collapse collapses, it is turned to the side of the road to cause a rockfall infiltration accident on the road .

Such a conventional rockfall prevention measures (1) is a steel wire 50 is installed on the support 20 at regular intervals, as shown in Figure 2a and 2b, respectively, through the clamp 22 to the support 20, respectively. It is fixed together and mounted side by side.

Therefore, when a load or earth pressure of the rockfall 40 is applied to any one position of the steel wire 50, a force is generated to propel all the struts 20 on both sides about the rockfall load position 44 in one direction. , All the tension of the steel wire 50 is directed to the rock load position 44 in one direction from both struts (20).

At this time, if the struts 20 are installed with sufficient supporting strength, they will remain self-supporting without falling down against the falling load caused by the rockfall 40, but if the amount of rockfall 40 or ingot When this increase exceeds the support strength of the struts 20, these struts 20 are all tensioned in one direction toward the rockfall load position 44, so the struts 20 are moments toward the rockfall load position 44. (M) was generated and fell toward the rockfall load position 44, and at the same time, the road fell.

The present invention is to solve the above-mentioned conventional problems, the object is that when the falling rock falls from the slope to act on the steel wire, the falling rock to support the rockfall by dispersing the load of the rock falling in both directions in each shore The beauty is to provide a rockfall prevention measure that is enhanced to prevent the propagation of the strut by effectively resisting the tendency to the load center point.

In addition, another object of the present invention is to prevent the fall of the shore by primarily distributing the load of rock falling in each direction in each shore, and at the same time to fall down to support the shore in the direction of the road using the load of rock falling from the slope In addition, by additionally resisting the load, the fall of the struts is prevented by effectively preventing the propagation of the struts as a whole, and providing a fall prevention measure with enhanced fall prevention functions to greatly enhance safety.

In order to achieve the above object, the present invention has a connecting means having a plurality of brackets protruding to both sides while maintaining a constant interval in the vertical direction of the support, both sides of the support corresponding to each bracket of the connection means A load distributing means having a plurality of pivoting levers arranged up and down in the upper part, hinge means for rotatably connecting respective pivoting levers of the load distributing means corresponding to the brackets of the connecting means, respectively; The upper and lower parts of the rotation levers each have a plurality of steel wires connecting the steel wires laterally through clamps to connect adjacent struts, and among the plurality of steel wires, falling rocks fall from both shores. When the tension is applied in one direction toward, the rock falls on the top or bottom of the dropped steel wire. The other wire is enhanced fall prevention function configured to distribute the load applying a tensile force falling rocks in the opposite direction against falling rocks from the loading position through the rotation lever of the load-distributing means with holding both sides in both directions to provide a rockfall prevention.

In addition, the load distribution means is preferably a plurality of rotation levers are arranged in turn up and down alternately on each side of the strut, the top layer rotation lever is a steel wire connected to the upper portion, the steel wire connected to the bottom of the top layer rotation lever Is in turn connected to an upper portion of the first pivot lever located on the opposite side of the strut, and the steel wire connected to the lower portion of the first pivot lever is in turn connected to an upper portion of the second pivot lever located on the opposite side of the strut at its lower portion. Rockfall prevention measures reinforced with fall prevention function configured to be repeatedly connected to the upper and lower shores, and the steel wires are connected to the lowermost connecting levers at the bottom thereof. To provide.

And the present invention preferably the load distribution means each of the rotation levers to form a bent portion between the central hinge connection portion and the two steel wire connection, respectively, to form a height difference, the hinge hinge of the hinge means in the central hinge connection portion Rotating lever is connected to the pivot axis around the hinge axis, the steel wire connecting portion is formed in both ends of the long hole in the vertical direction is connected to the steel wires by the clamps, the steel wires using the height difference formed in the bent portion The steel wires connected to both ends of the pivoting lever by protruding from the support provide a rock-fall prevention measure that is configured to be rotatable in opposite directions with respect to the hinge axis through the pivoting lever.

In addition, the present invention preferably further comprises a rockfall support means each having a pressure plate on the bottom back of the support, by using the load of the falling rock falling on the pressure plate to support the support in the road direction by holding the support firmly on the ground Provides a rockfall prevention measure with enhanced fall prevention capabilities configured to withstand the load of a rockfall to be felled.

And the present invention is preferably the rockfall support means is mounted on the back of each strut plate plate of the pressure plate through the ramp, the slope is mounted so that one end is rotatable through the first hinge at the intermediate point of the strut The vertical tilt angle is adjusted with respect to the vertically installed shore, and the other end of the ramp is mounted on the upper surface of the bearing plate to be rotated vertically through a second hinge, so that the additional tilt angle is adjusted with respect to the ramp. It provides a rockfall prevention measure that is reinforced with a fall prevention function configured so that the acupressure plate is tightly fixed to the ground in accordance with the slope of the ground where the strut is installed.

In addition, the present invention preferably provides a rockfall prevention measures to strengthen the fall prevention function is configured to allow the vegetation of plants by forming a plurality of holes to penetrate the upper and lower surfaces.

And the present invention preferably provides the rockfall prevention measures to strengthen the fall prevention function is provided with a blocking network on one side of the support.

According to the present invention, the pivoting levers of the load distributing means are mounted while maintaining a constant distance in the vertical direction of the struts, and the upper and lower portions of the pivot levers are connected side by side to each other to connect the struts adjacent to each other. And when the falling rocks fall on the steel wires and the falling rock load is applied to the steel wires, and the props are pulled in one direction toward the falling rock load position, other steel wires disposed at the upper or lower portion thereof are moved from the falling rock load position through the rotation lever of the load distribution means. Tension in both directions to the landlords disperses the concentration of rock loads in both directions.

Therefore, in the present invention, when rockfall falls from the slope and exerts a load on the steel wire, tension is applied in each shore as well as in one direction and in both directions, thereby dispersing and accepting such rockfall load. The fall can be effectively prevented.

In addition, according to the present invention, if the rockfall falls on the bearing plate by providing a rockfall support means having a pressure plate on the back of the support, the support is firmly supported on the ground by using the load of the rockfall, so that the rockfall is to fall in the direction of the road. It effectively resists the load of and prevents the conduction of the shore additionally.

Therefore, according to the present invention, by using the load distribution means, the load of the rockfall is first distributed in both directions to prevent the propagation of the strut, and the fall of the strut is further prevented by additionally preventing the propagation of the strut using the rockfall support means. Good effects can be obtained that are effectively delayed and greatly enhanced safety.

1 is a front view showing a rockfall prevention measure according to the prior art.
Figure 2a is an explanatory diagram showing a situation in which the rockfall load is concentrated in one direction toward the rockfall load position in the conventional rockfall prevention measures according to the prior art, the moment is generated in the struts, and the struts are turned over by shovel tilting.
Figure 2b is a cross-sectional view showing a state in which falling rocks or lumps fall on the back of the support in the prevention of rockfall according to the prior art.
Figure 3 is a front view showing the fall prevention measures to strengthen the fall prevention function according to the present invention.
Figure 4a is an exploded perspective view showing a structure in which the load distribution means provided in the rockfall prevention measures to strengthen the fall prevention function according to the present invention is mounted on the support.
Figure 4b is a cross-sectional view showing a state in which the load distribution means provided in the rockfall prevention measures to strengthen the fall prevention function according to the present invention is mounted on the support to distribute the rockfall load in both directions.
Figure 5a is an explanatory diagram showing a situation in which the struts are balanced by the tension force in one direction toward the rockfall load position from the steel wire subjected to the rockfall load in the rockfall prevention measures strengthening the fall prevention function according to the present invention is balanced. .
Figure 5b is a cross-sectional view showing a state in which the falling rock or lumps fall on the bearing plate disposed on the back of the support in the falling rock prevention measures strengthening the fall prevention function according to the present invention to maintain the support on the ground more firmly.
Figure 6a is an exploded perspective view showing the rockfall support means provided in the rockfall prevention measures to strengthen the fall prevention function according to the present invention.
Figure 6b is an operation explanatory diagram showing a state in which the inclination angle of the acupressure plate is freely adjusted in the rockfall support means provided in the rockfall prevention measures to strengthen the fall prevention function according to the present invention disposed on the back of the support in accordance with the slope of the ground.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

As shown in FIGS. 3 and 5b, the retaining wall 110 is constructed at the lowermost end of the slope 105 adjacent to the road, and the retaining wall 110 of the retaining wall 110 is reinforced. The support 120 is installed at a predetermined interval on the upper portion, and a plurality of steel wires 150 are installed to laterally connect the support 120.

Such a strut 120 may be provided with a blocking network 130 on one side thereof as in the related art, but the present invention is not limited to the installation of the blocking network 130 as described above, and without the blocking network 130. It includes both a structure in which the steel wire 150 is installed and a structure in which both the blocking network 130 and the steel wire 150 are installed.

The strut 120 is mounted on the retaining wall 110 in a stand alone manner, and is provided on the retaining wall 110 with an anchor bolt 122 at its lower end, and is formed of a pipe-like steel, a square. Includes all types of materials commonly used for rockfall protection, including section steel, "c" section steel, and "h" section steels.

And the falling rock prevention measures 100 strengthening the fall prevention function according to the present invention is applied to any one of the steel wires 150, such as the falling rock loads (120) toward the rocking load position 144 When pulled in one direction, the other steel wire 150 disposed above or below it is configured to dissipate the falling rock load in both directions from the falling rock location 144 to the struts 120.

To this end, the fall-prevention preventive measures 100 having enhanced fall prevention functions according to the present invention are provided with a plurality of brackets protruding to both sides while staggering each other while maintaining a predetermined interval in the vertical direction of each support 120 ( It has a connecting means 160 including 162.

The bracket 162 of the connecting means 160 is fixed to one side of the support 120 by welding, the center is formed so that the hinge means 180 can be mounted by forming a through hole 164, respectively.

In addition, in the present invention, the load distributing means 170 is disposed corresponding to each bracket 162 of the connecting means 160, and the load distributing means 170 is alternately disposed on both sides of the support 120. A plurality of pivoting levers 172 are provided.

The load distributing means 170 has a structure in which each of the rotation levers 172 is bent, as shown in FIG. 4A, and is disposed between the central hinge connection portion 174a and the steel wire connection portions 174b on both sides. Each inclined bent portion 174c is formed to form a height difference h.

In addition, the present invention is provided with a hinge means 180 for rotatably coupling the respective rotation lever 172 to the bracket 162 of the connecting means 160, respectively.

The hinge means 180 forms a head portion 182 having an enlarged diameter on one side thereof, and forms a male thread portion 186 on the other side thereof, and a hinge to which the female screw 188 is coupled to the male thread portion 186. The shaft 184 is configured such that the hinge shaft 184 rotatably mounts each pivot lever 172 to the bracket 162 of the connecting means 160.

That is, the hinge shaft 184 is inserted into the through hole 164 of the bracket 162 through the hinge ball 176 formed in the central hinge connection portion 174a of the rotation lever 172, the rear surface of the bracket 162 The female screw 188 is fixed to the male screw portion 186 that protrudes to attach the rotation lever 172 to the bracket 162, respectively.

At this time, the hinge shaft 184 has a diameter smaller than the inner diameter of the through hole of the hinge ball 176 and the bracket 162 of the rotation lever 172, thereby mounting the rotation lever 172 to the bracket 162. In this case, the pivot lever 172 is pivotally mounted about the hinge shaft 184.

In the pivoting lever 172, long holes 178 are formed in the steel wire connection portions 174b on both sides thereof, and the steel wires 150 are connected by the clamps 179a.

Such clamps 179a are conventional in the "U" type, and the steel wires 150 are aligned with upper and lower portions of the rotation lever 172 by tightening nuts 179b at the rear surface of the rotation lever 172. To be fixed.

As such, when the steel wires 150 are connected to the bracket 162 of the support 120 through the pivoting lever 172 of the load distributing means 170, as shown in FIG. 4B, the pivoting lever 172 Due to the height difference (h) formed in the bent portion (174c) is projected from the support 120, if any one of the wires 150 is pulled to one side, the other steel wire 150 to the opposite side It is configured to be rotated about the hinge axis 184 through the rotation lever 172 and pulled in the opposite direction.

In addition, the present invention includes a plurality of steel wires (150) for connecting the posts adjacent to each other in the transverse direction (이와), such that the plurality of steel wires 150 is mounted to the support structure 120 It is shown in Figure 5a.

That is, the plurality of pivot levers 172 of the load distributing means 170 are alternately arranged up and down alternately on both sides of each of the pillars 120, and the uppermost pivot lever 172a is disposed at each of the pillars 120. The steel wire 150 is connected to the side wire connecting portion 174b through the clamp 179a.

The steel wire 150 fixed to the lower steel wire connecting portion 174b of the uppermost rotating lever 172a has an upper steel wire connecting portion 174b of the first rotating lever 172b positioned on the opposite side of the support 120 at its lower portion. Fixed to the steel wire 150 connected to the lower portion of the first pivoting lever 172b in order to be connected to the upper portion of the second pivoting lever 172c positioned on the opposite side of the support 120 at its lower portion in order to be up and down. It is repeatedly connected to the support (120).

In addition, a steel wire 150 is connected to a lowermost connection lever 172f of the support 120, and in this manner, the plurality of steel wires 150 pass through a plurality of adjacent support posts 120 laterally. Extending side by side to connect a plurality of struts 120 integrally with each other.

Therefore, as illustrated in FIG. 5A, when the rockfall 140 falls on any one of the plurality of steel wires 150 connected to the support 120, the steel wires may fall on the rockfall load position 144. 150a) is pulled, and the struts 120 on both sides of the steel wire 150a are pulled in one direction toward the rockfall load position 144.

However, the other steel wires 150b and 150c disposed above or below the steel wire 150a to which the rockfall load is applied are pulled in the opposite direction through the rotation lever 172 of the load distributing means 170 so that the rockfall load Tension in both directions from position 144 to posts 120 and distributes the rockfall load.

Here, the one-way tension force that the falling rock 140 falls on the steel wire 150a so that the struts 120 on both sides are directed to the falling rock load position 144, the load distribution means 170 on the upper and lower portions of the steel wire 150a. It can be seen that the direction of action is opposite to each other as compared to the bidirectional tension of the other steel wires 150b and 150c which are directed from the rockfall load position 144 to the struts 120 on both sides through the rotation lever 172 of have.

According to the present invention through the structure, when the rockfall 140 falls from the slope 105 to exert a load on the steel wire 150, one direction in the steel wire 150a to which a drop load is applied in each support 120 is applied. In addition to the tension force, the two-way tension force formed through the rotation lever 172 of the load distributing means 170 in the upper and lower steel wires 150b and 150c thereof acts to distribute and accommodate such a rockfall load. Resisting the support posts to 144, and effectively prevents the fall of the support posts 120 on the road side. Therefore, in each strut 120, the two-way tension force opposite to the one-way tension force is applied simultaneously, so that the tension force due to the falling rock load is dispersed and balanced to maintain stable.

And the rockfall prevention measures 100 strengthening the fall prevention function according to the present invention further includes a rockfall support means 190 having acupressure plate 192 on the lower back of each support 120, as shown in Figure 6a .

The rockfall support means 190 of the rockfall 140 to conduct the strut 120 in the direction of the road by holding the strut 120 firmly on the ground by using the load of the rockfall 140 dropped to the pressure plate 192. It is configured to withstand loads.

The rockfall support means 190 is a plate-shaped pressure plate 192 is mounted on the back of each support 120 through the ramp 194, the ramp 194 is one end of the middle of the support 120 Mounted to be rotatable through the first hinge 196 at the point is connected to adjust the vertical tilt angle with respect to the vertically installed strut 120.

In addition, the other end of the ramp 194 is mounted to the upper surface of the pressure plate 192 to be rotated up and down through the second hinge 198 is connected to the additional tilt angle adjustment with respect to the ramp 194.

Accordingly, as shown in FIG. 6B, the pressure plate 192 is fixedly adhered to the ground in accordance with the inclination of the ground on which each support 120 is installed.

In addition, such a pressure plate 192 is formed with a plurality of holes 192a to penetrate the upper and lower surfaces, such that the roots of the plants can pass through such holes 192a to enable vegetation of plants on the ground. It is.

As shown in FIG. 5A, the rockfall prevention measure 100 having the fall prevention function according to the present invention configured as described above is a rockfall on any one of the plurality of steel wires 150 connected to the support 120. When the 140 falls, the steel wire 150a is pulled by the rockfall load, and when the steel wire 150a is pulled in this way, the struts 120 on both sides thereof are directed to the rockfall load position 144 through the rock wire 150a. It is pulled in one direction.

However, as shown in FIG. 4B, the other steel wires 150b and 150b disposed above or below the steel wire 150a to which the rockfall load is applied, respectively, are pivot levers 172 of the load distributing means 170. It is pulled in the opposite direction through, the pivoting lever 172 is rotated in the opposite direction about the hinge axis 184 in the center thereof in the opposite direction, the upper portion of the corresponding steel wire 150a to which the rockfall load is applied Or other steel wires 150b and 150c disposed below are tensioned in both directions from the rockfall load position 144 to the struts 120 and consequently distribute the rockfall load to both struts 120.

In addition, the rockfall support means 190 disposed on the back of the support 120, as shown in Figure 5b, when the rockfall 140 falls to the acupressure plate 192, rockfall 140 loads the pressure plate In addition to (192) it is in close contact with the ground (G).

When the pressure plate 192 is in close contact with the ground (G) as described above, the pressure plate 192 is integrally connected to the back surface of the support 120 through the inclination table 194, so the support 120 is coupled with the pressure plate 192. Maintained firmly in the ground (G) it is possible to effectively resist the load of the rockfall 140 to conduct the strut 120 in the road direction.

As described above, the present invention mounts the rotation levers 172 of the load distributing means 170 so as to be staggered while maintaining a predetermined distance to both sides in the vertical direction of the support 120, and through the clamps 179a at the upper and lower portions thereof, respectively. The steel wires 150 are connected side by side in a lateral direction to integrally connect the struts 120 adjacent to each other.

In this state, when the rockfalls 140 fall on the steel wires 150 and the rock load is applied to the steel wires 150, the steel wires 150a are directed toward the rockfall load position 144 in one direction. The other wires 150b and 150b disposed in the upper or lower portion of the steel wire 150 to which the tension force acts in one direction are thus pulled down through the rotation lever 172 of the load distributing means 170. 144 is respectively tensioned in opposite directions from the opposite side toward the struts 120 to disperse the concentration of tension force toward the rock load site 144 in both directions.

Therefore, in the present invention, when the rockfall 140 falls from the slope 105 and exerts a load on the steel wire 150, the tension force acts in each direction 120 as well as in one direction and in both directions, thereby causing the rockfall 140 By dispersing and receiving the concentrated load into the plurality of struts 120, the fall of the struts 120 to the rockfall load position 144 may be effectively prevented.

In addition, the present invention is provided with a rockfall support means 190 having acupressure plate 192 on the back of the support 120, when the rockfall 140 falls on the acupressure plate 192, acupressure plate 192 through the inclined table 194. Since struts 120 connected to) are firmly fixed to the ground (G) by using the load of the rockfalls 140, the struts 120 are effectively resisted against the load of the rockfalls 140 to conduct the struts 120 in the road direction. Additionally prevent the fall of

As a result, the present invention primarily distributes the load of the rockfall 140 in both directions through the load distribution means 170 and the steel wire 150 mounted on the support 120 to prevent the road side conduction of the support 120. By fixing the support 120 to the ground (G) using the rockfall support means (190), it can additionally prevent the fall of the support (120), effectively delaying the conduction of the support (120) as a whole, It will greatly enhance safety.

An embodiment of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The protection scope of the present invention is limited only by the matters described in the claims,

Those skilled in the art of the present invention can change and change the technical idea of the present invention in various forms. Accordingly, such improvements and modifications are within the scope of the present invention as long as they are obvious to those skilled in the art.

1 ...... Conventional rock fall prevention measures 5,105 ......
10,110 ..... retaining wall 20,120 ......
22 ..... clamp 30,130 ..... screen
40,140 ....... Rockfall 44,144 ...... Rockfall Load Position
50,150 ..... liner
100 ..... Rockfall prevention measures with enhanced fall prevention
122 ...... anchor bolt 150a .....
150b, 150c ..... other wires 160 ......
162 ...... Bracket 164 ...... Through hole
170 ...... Load distribution means 172 ...... Rotary lever
172a ..... Top floor pivot lever 172b ...... 1st pivot lever
172c ..... 2nd pivoting lever 172f ......
174a ..... Hinge connection 174b ...... Wire connection
174c ..... Bend 176 ...... Hinge Ball
179a ..... Clamp 179b ..... Nut
180 ...... Hinge Means 182 ...... Head
184 ...... Hinge shaft 186 ...... Male thread
188 ...... Female thread 190 ...... Rockfall support means
192 ..... pressure plate 192a ..... hole
194 .. Ramp 196 ..... Hinge 1
198 ...... Second hinge G ...... Soil
h ....... height difference M ...... moment

Claims (7)

It is provided with a connecting means having a plurality of brackets protruding on both sides while maintaining a constant interval in the vertical direction of the support,
A load distributing means having a plurality of pivoting levers arranged up and down on both sides of the strut corresponding to each bracket of the connecting means, each rotating lever of the load distributing means corresponding to the bracket of the connecting means, respectively; With hinge means for enabling connection,
The upper and lower portions of the respective rotation levers are provided with a plurality of steel wires that connect the steel wires laterally through clamps to connect adjacent struts, and among the plurality of steel wires, falling rocks fall from both shores. When tension is applied in one direction towards the rockfall loading position, the other steel wire placed above or below the steelfall on which the rockfall has fallen falls in the opposite direction from the rockfall load position to both struts via the pivoting lever of the load distributing means. Rockfall prevention measures with enhanced fall prevention function, characterized in that configured to distribute the rock load in both directions by applying a. The method of claim 1, wherein the load distribution means
A plurality of pivoting levers are alternately arranged up and down alternately on each side of each strut, the uppermost pivoting lever has a steel wire connected to the upper portion thereof, and the steel wire connected to the lower portion of the uppermost pivoting lever has a first pivotal position located opposite to the shoreline at its lower portion. The steel wire is connected to the upper part of the lever, and the steel wire connected to the lower part of the first pivoting lever is repeatedly connected to the strut up and down in turn in such a manner that it is connected to the upper part of the second pivoting lever located on the opposite side of the strut at the lower part thereof. A steel wire is connected to the lower part, and the plurality of steel wires are configured to connect the plurality of adjacent posts in a transverse direction to be integrally integrated. The method of claim 2, wherein the load distribution means
Each pivoting lever forms a bent portion between the central hinge connection portion and both steel wire connection portions to form a height difference, and the hinge hinge of the hinge means is connected to the bracket so that the pivoting lever can pivot about the hinge axis. The steel wire connecting portion has long holes formed in both ends in an up and down direction, respectively, so that the steel wires are connected by clamps, and the steel wires are protruded from the support using the height difference formed at the bent portion, so that both ends of the rotation lever are disposed. The steel wires connected to the falling rock prevention function, characterized in that the pivoting lever is configured to be able to rotate in opposite directions with respect to the hinge axis. The method of claim 1 wherein the post
It further comprises a rockfall support means each having a pressure plate on the bottom back of the bottom, by using the load of the falling rock falling on the pressure plate to hold the support firmly on the ground to resist the load of rockfall to propel the shore in the direction of the road Rockfall prevention measures which strengthened fall prevention function characterized by. The rockfall support means of claim 4, wherein
A plate-shaped acupressure plate is mounted on the back of each shore through an inclined platform, and the inclined platform is mounted such that one end thereof is rotatable through a first hinge at an intermediate point of the shore so that the vertical tilt angle can be adjusted with respect to the vertically installed shore. The other end of the inclined plate is mounted on the upper surface of the acupressure plate so as to be rotated up and down through a second hinge so that the inclined angle of the inclined plate is additionally adjusted so that the pressure plate is in close contact with the ground in accordance with the inclination of the ground where the support is installed. Rockfall prevention measures to strengthen the fall prevention function, characterized in that configured to be fixed. According to claim 5, wherein the pressure plate is
Rockfall prevention measures to strengthen the fall prevention function, characterized in that a plurality of holes are formed to penetrate the upper and lower surfaces to allow vegetation of plants. The rockfall prevention measure of claim 1 or 4, wherein the prop is provided with a blocking network at one side thereof.

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