KR101174619B1 - Rockfall protection fence for distributing and absorbing impect energy - Google Patents

Abstract

The present invention is to provide a rockfall prevention fence that the distribution and absorption of impact energy so that all the wire rope behaves together so that the distribution of rockfall impact force is evenly distributed over the entire wire rope, the specific means of the present invention, concrete structure A plurality of struts arranged and placed at regular intervals therein; A plurality of wire ropes arranged in the transverse direction at a predetermined interval in the height direction on the support; One or more distribution cables disposed longitudinally between adjacent struts and connected to the plurality of wire ropes through rings, the rings being connected by flexible strands or circular rings; And a buffer means for selectively inserting one or more of the plurality of wire ropes to be fixed to one side of the post and absorbing the impact applied to the wire ropes by elastic deformation.

Description

Rockfall protection fence for distributing and absorbing impect energy}

The present invention relates to a rockfall prevention fence provided with a wire rope, and more particularly to a rockfall prevention fence to improve the rockfall support ability by allowing the distribution and absorption of impact force to the entire wire rope.

A rockfall prevention facility is a structure that is installed to prevent and prevent traffic obstacles, damage to road structures or road facilities, loss of property, and human life from disasters caused by falling rocks on the incision surface and earth and sand collapse.

The protection methods of rockfall prevention facilities include rockfall protection nets, rockfall prevention fences, rockfall protection retaining walls, and rock tunnels. Here, the rockfall prevention fence is a facility that prevents the damage caused by falling rocks by connecting the landslides with the landslides with wire ropes and wire mesh to absorb the energy of falling rocks from the incision surface.

The existing rockfall prevention fence adopts a method of placing pillars on a concrete structure at regular intervals, and arranges a plurality of wire ropes horizontally at predetermined heights and connects them to the pillars. Therefore, when a strong impact force is received by the rock, the net is torn and the wire rope is cut. That is, the wire rope between the pillars is supported only by the pillars, and thus, a problem arises that rocks are penetrated under the lower wire ropes.

Domestic registered utility model No. 20-0287832 (wire rope spacing device for falling rock fence) is arranged more tightly on the lower side than on the upper side of any equally spaced wire ropes installed across the strut and the strut. It is provided perpendicularly to the center of the wire rope between the arranged struts, and has a gap holding means for supporting the gap between the wire ropes so that the gap between the wire ropes can be maintained. It is a technique that increases the falling-off effect of the fence by the gap maintaining means having a rigidity at the center point of the wire rope so as to make the gap between the lower side wire ropes more dense and at the same time maintain the gap at all times. However, the above technology has the advantage that the gap between the lower wire rope is maintained, but the energy absorbing capacity of the prop is lowered to inhibit the rigidity, there is a problem that deformation due to the shock absorption of the wire rope or wire mesh itself.

Accordingly, it is an object of the present invention to provide a rockfall prevention fence capable of distributing and absorbing impact energy such that all wire ropes behave together to distribute the rockfall impact force evenly over the entire wire rope.

In addition, another object of the present invention is to prevent the impact energy to be absorbed wire rope to prevent deformation of the wire rope, increase the support capacity of rockfall, rockfall prevention fence capable of distribution and absorption of impact energy improved the impact resistance rigidity of the shore In providing.

In order to achieve the above object,

A plurality of struts arranged and placed in the concrete structure at predetermined intervals;

A plurality of wire ropes arranged in the transverse direction at a predetermined interval in the height direction on the support;

One or more distribution cables disposed longitudinally between adjacent struts and connected to the plurality of wire ropes through rings, the rings being connected by flexible strands or circular rings; And

At least one of the plurality of wire ropes is selectively inserted into and fixed to one side of the support, and includes shock absorbing means for absorbing the impact applied to the wire ropes with elastic deformation;

The buffer means,

A thimble to which the wire rope is wound;

The thimble is installed to surround the wound portion of the wire rope wound around the thimble in a circular shape, characterized in that it further comprises a plurality of safety rings to prevent the wire rope from the position deviation when the thimble is crushed.

Also according to the invention,

The distal end of the wire rope is bent for a predetermined period to form a clip fixing part fixed by the wire rope clip.

The rockfall prevention fence in which the impact energy is distributed and absorbed according to the present invention is distributed by the distribution cable, while the distribution of the rockfall impact force is uniformly distributed over the entire wire rope by the distribution cable.

In addition, by absorbing rockfall impact force by arched spring and thimbles, deformation of wire rope is prevented and rockfall support ability is improved. Therefore, the impact resistance rigidity of the shore is also improved.

1 is a block diagram of a rockfall prevention fence made of the distribution and absorption of impact energy according to the present invention.
Figure 2 (a) and (b) is a configuration diagram of various forms of distribution cable applied to the present invention.
Figure 3a and Figure 3b is a various configuration of the arched spring applied to the present invention.
4 is an end processing configuration diagram of a wire rope according to the present invention.
5A is an enlarged view seen from line AA of FIG. 1.
Figure 5b is an operating state showing the buffer absorption of the arched spring applied to the present invention.
Figure 6a is a front view showing a buffer configuration using a thimble applied to the present invention.
Figure 6b is a side cross-sectional view of the wire rope wound shim applied to the present invention.
Figure 7 is a behavior of the distribution cable applied to the present invention.

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

1 is a block diagram of a rockfall prevention fence is made of the distribution and absorption of impact energy according to the present invention, Figure 2 (a) and (b) is a configuration diagram of various forms of distribution cable applied to the present invention.

1 to 2 as shown in the concrete structure 5, a plurality of struts 10 are installed upright. The strut 10 may be made of a material such as steel pipe, section steel, FRP, aluminum. In the present embodiment, the support 10 has a structure in which rigidity is reinforced by filling concrete in the steel pipe.

The strut 10 is provided with a plurality of wire ropes 12 which are installed in the transverse direction at regular intervals in the vertical direction. The wire rope 12 has a structure in which a plurality of lecturers are twisted.

In this case, for convenience of installation of the wire rope 12, it is preferable that the guide pipe 14 is inserted and installed as shown in FIG. 4 in the pipe insertion hole 10a formed at predetermined intervals of the support 10. Therefore, the guide pipe 12 is embedded in the concrete inside the steel pipe. 4 is an end processing configuration diagram of a wire rope according to the present invention.

Distributing cables 20 are installed between the adjacent posts 10 and 10 in the longitudinal direction and are connected to the plurality of wire ropes 12. Two or more distribution cables 20 may be installed as the distance between adjacent pillars 10 and 10 increases. The distribution cable 20 distributes the impact applied to the wire rope 12 due to the falling rocks in two directions (Fh, Fv) as shown in FIG. 7 so that the impact energy is transmitted to all five wire ropes 12 in this embodiment. To function. 7 is a diagram illustrating a behavior of a distribution cable according to the present invention. The distribution cable 20 is composed of a plurality of rings 21 inserted into the wire rope 12 and a flexible strand 22 connecting the plurality of rings 21 as shown in FIG. In this case, the strand 22 operates flexibly to cause all the behavior of the wire rope 12 flexibly. Instead of the strand 22, a plurality of circular rings 23 may be connected as shown in FIG. 2 (b).

The wire rope 12 is provided with an arched spring 30 as a cushioning means to absorb the impact energy of rockfall to prevent shear or deformation of the wire rope 12 and increase the rigid resistance of the support 10. Arch-shaped spring 30 is made of a plate body as shown in Fig. 3 (a) several times the inner arc portion 31, the outer arc portion 32 and both ends of the inner and outer arc portion to be suitable for the circular post 10 It is comprised by the elastic bending part 33 connected by bending. In the center of the inner and outer arc portions 31 and 32, wire rope insertion holes 31a and 32a are formed to penetrate in the same straight line to insert the wire rope 12. 3A is a configuration diagram of one embodiment of an arched spring applied to the present invention.

The arc plate spring 30 may be further provided with an arc plate 34 that arcs in the opposite direction to the inner arc portion 31 (or outer arc portion) to increase its elastic restoring force. In addition, the arch plate spring 30 may further include a disc spring 35 disposed between the inner arc portion 31 and the outer arc portion 32, as shown in FIG. Figure 3b is a configuration diagram of another form of the arched spring applied to the present invention. In this embodiment, the buffer means is configured in a semi-circular arch shape, but may appear in a modified form according to the shape of the support (10).

At this time, the arcuate spring 30 has a stopper 15 fixed to the wire rope 12 on one side thereof, as shown in (a) and (b) of FIG. 5. Therefore, when the wire rope 12 is tensioned, the arched spring 30 is subjected to the compressive force by the stopper 15. Figure 5a is an enlarged view seen from the line A-A of Figure 1, Figure 5b is an operating state diagram showing the buffer absorption of the arched spring applied to the present invention.

In this embodiment, the arched spring 30 is installed in a plurality of wire ropes 12 by one step down and up and down, but is not limited to this installation arrangement.

6A and 6B, a thimble 40 having an elastic restoring force may be further installed on the wire rope 12 as an auxiliary means of the shock absorbing means. The wire rope 12 is wound around the thimble 40 once. More than one thimble 40 may be installed in one wire rope 12.

The thimble 40 is provided with a plurality of safety rings 50 to prevent the wire rope 12 from being displaced when tension is generated in the wire rope 12 due to rockfall impact energy and the thimble 40 is crushed. Safety ring 50 is configured in a ring shape having a cut surface. Therefore, the safety ring 50 is installed so as to surround the wire rope 12 and the thimble 40 as shown in Figure 6b open.

On the other hand, the end of the wire rope 12 is bent a predetermined section to constitute a clip fixing portion 17 fixed by the wire rope clip (16). In this case, the clip fixing part 17 is disposed at a predetermined interval from the arched spring 30 so that slip occurs when tension of the wire rope 12 occurs.

The operation of this embodiment configured as described above will be described.

First, when a rockfall 100 is generated and a strong impact force is applied to the wire rope 12, as shown in FIG. 7, the plurality of wire ropes 12 are moved together by the distribution cable 20, and thus the impact force Fh and Fv may be reduced. Distribution takes place. Therefore, the tension generated in one wire rope 12 is reduced as much as the impact force is distributed.

At the same time, while the clip fixing part 17 fixing the end of the wire rope 12 is moved, a certain section slip is generated. The relaxation slip of the wire rope 12 absorbs a strong impact force primarily.

Since the arch plate spring 30 is crushed and compressed as shown in FIG. 5 (b) to generate elastic restoring force, so that the impact energy of the rockfall is secondarily absorbed and transferred to the support 10. Therefore, the strut 10 is significantly reduced impact energy is transmitted, so that the first prop position of the strut 10 can be maintained, thereby increasing the rock-blocking effect.

On the other hand, when the crushed the thimble 40 with the tension applied to the wire rope 12 by the impact force of the rockfall, as the elastic restoring force of the thimble 40 is absorbed by the impact energy of the rockfall in the third.

As described above, the rockfall prevention fence of the present invention distributes the strong impact force of the rockfall to the plurality of wire ropes 12 through the distribution cable 20, and at the same time absorbs the primary by the relaxation slip of the wire rope 12, the arch plate shape The impact energy is secondarily absorbed through the elastic compression of the spring 30, and the impact energy is absorbed thirdly by the elastic restoring force of the crushed thimble 40. In this way, the impact force applied to the wire rope 12 is dispersed and absorbed, so that the falling ability of supporting the rock rope 12 is improved, and since the support 10 is indirectly impacted by the falling rock, it is possible to prevent the fall of rigidity. Even the strong impact force of the post 10 can maintain the standing posture.

10: Holding
12: wire rope
20: distribution cable
30: arched spring
40: thimble

Claims (2)

A plurality of struts 10 installed in concrete structures at predetermined intervals;
A plurality of wire ropes 12 arranged in the transverse direction at regular intervals in the height direction on the support 10;
Disposed longitudinally between adjacent struts 10, 10 and connected to the plurality of wire ropes 12 through rings 21, the rings 21 having a flexible strand 22 or circular ring 23; One or more distribution cables 20 connected to each other;
One or more of the plurality of wire ropes (12) selectively inserted and fixed at one side of the support (10), and including shock absorbing means for absorbing the impact applied to the wire ropes (12) with elastic deformation;
The buffer means,
A thimble 40 on which the wire rope 12 is wound;
It is installed so as to surround the wound portion of the wire rope 12 wound on the thimble 40 and the thimble 40 in a circular manner, a plurality of plural to prevent the wire rope 12 from being separated when the thimble 40 is crushed Rockfall prevention fence capable of distributing and absorbing impact energy, characterized in that it further comprises two safety rings (50). The method according to claim 1,
The end portion of the wire rope 12 is bent a predetermined section to form a clip fixing portion 17 is fixed by the wire rope clip 14, characterized in that the impact energy distribution and absorption is possible fence.

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