KR20200120025A - guard fence of Prevention Against Falling Stone - Google Patents

Abstract

The present invention relates to a high-tension falling stone prevention means. According to the present invention, the high-tension falling stone prevention means includes: an H-beam supporter (130) fixed onto a concrete foundation through a plurality of anchors (150), and preventing the torsion of an H-beam (100); the H-beam (100) assembled with an upper part of the H-beam supporter (130); and a shock absorbing part (110) provided in an upper part of the H-beam (100) and reducing shock energy working when soil and stone, floating impurities, falling stones and the like flow into the high-tension falling stone prevention means. The shock energy is primarily reduced through the elastic deformation of a net (140) and a wire rope (115) connected between an H-beam (100) and an H-beam (100) in a state in which a plurality of H-beams (100) are installed at regular intervals and then, the shock energy is secondarily reduced with the frictional resistance of the anchors (150). According to the present invention, the shock absorbing part provided in an upper part of an H-beam damps shock energy working when soil and stone, floating impurities, falling stones and the like flow into the high-tension falling stone prevention means, and furthermore, the H-beam supporter provided in a lower part of an H-beam supports the lower part of the H-beam so as to prevent torsion and, as a result, the quality and reliability of the falling stone prevention means can be considerably improved.

Description

Guard fence of Prevention Against Falling Stone

An embodiment of the present invention relates to a high-tension rockfall prevention measure, and more specifically, the impact energy that acts when earth and rock flows, transport debris, and rockfalls enter the high-tensile rockfall prevention measure, and a shock absorber provided at the top of the H-beam attenuates the shock energy. In addition, the H-beam support provided at the lower end of the H-beam supports the lower end of the H-beam to prevent distortion, and as a result, the quality and reliability of the rockfall prevention measure can be greatly improved.

As is well known, a rockfall prevention measure is a structure installed to protect facilities, cars, or people under a cliff from rockfall.

In particular, the rockfall prevention measure is to drive a post with H-beam or the like on the concrete foundation, and suppress the rockfall with H-beam or wire mesh. In some cases, there is a structure that absorbs shock by attaching waste tires or the like side by side to the falling part of the rockfall. It is widely used in the preservation project of steep slopes, and is also called a rockfall prevention measure.

The conventional rockfall prevention measures useful as described above have the following problems.

That is, as shown in FIG. 1, in the prior art, since the bracket is attached to the H beam by welding or the like, the welding portion becomes brittle when it takes a long time, resulting in a large problem that the bracket is separated from the H beam.

In addition, in the prior art, the wire rope is fastened to the bracket by a shackle.If the shackle is tightened tightly, the wire rope does not move, and when the shackle is tightened loosely, the wire rope moves to the side. During the first impact of the H-beam, energy was transmitted to the end as it was, resulting in a large problem that the H beam was damaged.

In addition, since the lower end of the H beam of the prior art is fastened in a weak manner in which only pillars are installed, the H beam is twisted by the force transmitted to the H beam when impact energy is generated, making it difficult to maintain the strength of the H beam. This happened.

In order to solve the above problems, the following prior art documents have been developed in the prior art, but there is still a large problem that cannot solve the problems of the prior art at once.

Republic of Korea Patent Publication No. 1036910 (2011. 05. 18) has been registered. Republic of Korea Patent Publication No. 1572504 (2015. 11. 23) has been registered. Korean Registered Patent Publication No. 1572505 (2015. 11. 23) has been registered.

The present invention was devised to solve the problems of the prior art as described above, and the first purpose is to provide an H-beam with an impact absorbing part, a wire rope, a reinforcing part, and an H-beam support. The second object of the present invention is to reduce the impact energy of the impact absorbing unit provided at the top of the H-beam, and to reduce the impact energy of the impact energy that acts when earth and stone flows, pollutants, and rockfalls flow into the high-tensile rockfall prevention measure. The H-beam support provided at the bottom is to support the lower end of the H-beam to prevent distortion, and the third purpose is that the energy transmitted to the wire rope in the event of a local impact pulls the wire rope downward and The 4th purpose is to reduce the energy transmitted to the end of the wire rope when the secondary energy is generated by transferring energy to the side H beam, and the fifth purpose is to reduce the energy applied to the end. The impact energy that acts when miscellaneous objects and rockfalls enter the high-tensile rockfall prevention measures is primarily attenuated by the elastic deformation of the net, and the remaining impact energy is to be transferred to the wire rope, and the sixth purpose is the impact transmitted to the wire rope. The energy is secondarily attenuated by wire rope and net ring deformation and frictional resistance, and the residual impact energy is transferred to the anchor, and the seventh purpose is that the impact energy transferred to the anchor is finally transferred to the anchor made of flexible members. The eighth purpose is to prevent the H-beam from being damaged by providing an impact absorber at the top of the H-beam so that energy is not transmitted to the end of the first impact such as a rockfall. The ninth purpose is to maintain the strength of the H-beam by assembling the reinforcement part provided at the bottom of the H-beam and the H-beam support, even if impact energy is generated, so that distortion does not occur. As a result, it provides high-tensile rockfall prevention measures that can significantly improve the quality and reliability of rockfall prevention measures.

In order to achieve this object, the present invention is fixedly installed using a plurality of anchors on a natural ground or concrete foundation, and an H beam support for preventing twisting of the H beam; H-beam assembled and installed on the top of the H-beam support; An impact absorbing unit provided at the upper end of the H-beam and attenuating the impact energy acting when earth and stone flows, pollutants, and rockfalls enter the high-tensile rockfall prevention measures; And a plurality of H-beams installed at regular intervals, and the impact energy is firstly reduced by using the elastic deformation of the circular and high-strength net fastened to the wire rope connected between the H-beam and the H-beam, and the anchor has a high strength with ductility. It provides a high-tensile rockfall prevention measure characterized by reducing the impact energy secondarily by the frictional resistance of the steel wire (wire rope).

As described in detail above, the present invention is to be provided with a shock absorbing part, a wire rope, a reinforcing part, and an H-beam support in the H beam.

The present invention according to the above-described technical configuration allows the shock absorber provided at the upper end of the H beam to attenuate the impact energy, and the impact energy that acts when the earth and stone flows, transport debris, and rockfalls enter the high-tensile rockfall prevention measures. The H-beam support provided at the lower end of the H-beam is designed to support the lower end of the H-beam to prevent distortion.

In addition, in the present invention, when a local impact occurs, the energy transmitted to the wire rope pulls the wire rope downward, thereby reducing the energy transmitted to the H beam.

In addition, in the present invention, when secondary energy is generated, energy is transmitted to the side H beam to reduce the energy applied to the ends of the wire rope.

In addition, in the present invention, the impact energy acting when earth and stone flows, pollutants, and rockfalls flow into the high-tensile rockfall prevention measure is primarily attenuated by the elastic deformation of the net, and the residual impact energy is transmitted to the wire rope.

In addition, in the present invention, the impact energy transmitted to the wire rope is secondarily attenuated by the wire rope and the net ring deformation and frictional resistance, and the residual impact energy is transmitted to the anchor.

In particular, in the present invention, the impact energy transmitted to the anchor is finally transmitted to the ground by an anchor made of a flexible member.

In addition, the present invention is to prevent the H beam from being damaged by providing an impact absorbing part on the upper end of the H beam so that energy is not transmitted to the end as it is during a primary impact such as a rockfall.

In addition, according to the present invention, when the reinforcing part provided at the lower end of the H beam and the H beam support are mutually assembled, even if impact energy is generated, distortion does not occur, so that the strength of the H beam can be maintained.

As a result, the present invention is a very useful invention capable of significantly improving the quality and reliability of a rockfall prevention measure.

Hereinafter, a preferred embodiment of the present invention for achieving this effect will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of a conventional rockfall prevention measure.
Figure 2 is a front view of the installation state of the high-tensile rockfall prevention measures applied to the present invention.
Figure 3 is a side view of the installation state of the high-tensile rockfall prevention measures applied to the present invention.
Figure 4 is an enlarged configuration of the main portion of the upper end of the H beam applied to the present invention.
Figure 5 is an enlarged configuration diagram of the lower part of the H-beam applied to the present invention.
Figure 6 is a front view showing the H beam and H beam support applied to the present invention.
Figure 7 is a side view showing the H beam and H beam support applied to the present invention.
8 is an exploded perspective view showing an H beam and an H beam support applied to the present invention.

The high-tension rockfall prevention measure applied to the present invention is configured as shown in FIGS. 2 to 8.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

In addition, terms to be described later are terms set in consideration of functions in the present invention and may vary according to the intention or custom of the producer, so the definition should be made based on the contents throughout the present specification.

In addition, the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of description, so the present invention is not necessarily limited to those shown in the drawings.

First, the present invention is fixedly installed using a plurality of anchors 150 on a concrete foundation in the ground, and an H-beam pedestal 130 for preventing twisting of the H-beam 100 is provided.

And the present invention is provided with an H-beam 100 that is assembled and installed on the upper end of the H-beam pedestal 130.

In addition, the present invention is provided on the upper end of the H-beam 100, and is provided with a shock absorbing unit 110 for attenuating the impact energy acting when the earth and stone flows, transport debris, and rockfalls enter the high-tensile rockfall prevention measures.

In particular, the present invention is a circular and high-strength net 140 fastened to a wire rope 115 connected between the H beam 100 and the H beam 100 in a state in which a plurality of H beams 100 are installed at regular intervals. The impact energy is firstly reduced by using the elastic deformation, and the anchor 150 provides a high-tensile rockfall prevention measure characterized in that the impact energy is secondarily reduced by the frictional resistance of a high-strength steel wire (wire rope) having ductility.

On the other hand, the H-beam bracket 130 applied to the present invention is configured as follows.

In other words. The present invention is provided with a plurality of fastening holes 131 formed at regular intervals so that the anchor 150 is fastened.

In addition, the present invention is formed protruding from the upper end of the H-beam pedestal 130, and is provided with at least one flange 132 formed with a fastening hole 133 so as to be assembled by bolts to the H-beam 100.

In addition, the present invention is formed protruding from either one or both ends of the upper end of the H-beam pedestal 130, and is provided with a flow preventing portion 134 for preventing the separation and movement of the H-beam (100).

In addition, the bolts are inserted into the fastening holes 121 and 133 at both sides of the lower end of the H beam 100 in the present invention to prevent the twisting of the H beam 100 even when impact energy is generated. A reinforcing part 120 to prevent is provided.

In addition, the flow preventing portion 134 of the present invention is provided with a shackle connecting portion 135 having a fastening hole 136 formed therein so as to connect the net 140 by fastening the shackle 145.

On the other hand, the shock absorbing unit 110 applied to the present invention is configured as follows.

That is, in the present invention, a seating groove 111 having a concave groove is provided so that the wire rope 115 is located in the center of the upper end.

In addition, the present invention is provided with at least one bolt 113 that is horizontally fastened to the side fastening hole 112 of the H beam 100 and the mounting groove 111 to prevent the wire rope 115 from being separated.

At this time, it is preferable that the upper end of the impact absorbing unit 110 applied to the present invention is formed in an "M" shape.

On the other hand, a bracket 116 for connecting the wire rope 115 by fastening the shackle 145 to the fastening hole 117 is provided at one or both corners of the impact absorbing unit 110 applied to the present invention, It goes without saying that the tip of the wire rope 115 is connected to the anchor 150 in the ground.

At this time, at least one bracket 116 is formed at the upper edge of the H beam 100.

Finally, a rubber plate that protects the H-beam 100 and the flow-prevention part 134 from colliding with each other and absorbs the shock while closely contacting the H-beam 100 to the side of the flow prevention part 134 of the present invention ( 137) is provided.

On the other hand, the present invention can be variously modified and take various forms in applying the above-described components.

And it should be understood that the present invention is not limited to the particular form mentioned in the detailed description above, but rather, including all modifications and equivalents and substitutes within the spirit and scope of the present invention as defined by the appended claims. It should be understood as.

When explaining the effects of the high-tensile rockfall prevention measures of the present invention configured as described above are as follows.

First of all, the present invention reduces the impact energy of the impact energy that acts when earth and stone flows, pollutants, and rocks flow into the high-tensile rockfall prevention measures, and the impact absorber provided at the top of the H beam attenuates the impact energy, and the H beam provided at the bottom of the H beam. The pedestal supports the lower end of the H-beam to prevent distortion, and as a result, the quality and reliability of the rockfall prevention measure can be greatly improved.

To this end, Figure 2 applied to the present invention is a front view of the installation state of the high-tensile rockfall prevention measures applied to the present invention, Figure 3 is a side view of the installation state of the high-tensile rockfall prevention measures applied to the present invention, a plurality of anchors 150 on the concrete foundation in the ground After construction, H-beam is installed, and in particular, after vertically erecting a plurality of H-beam brackets 130 and H-beams 100 at regular intervals, a wire rope 115, a net 140, and an anchor 150 are used. Therefore, a rockfall prevention measure is installed.

In addition, Figure 4 is an enlarged configuration diagram of the upper portion of the H beam 100 applied to the present invention, by connecting the wire rope 115 to the bracket 116 to secure the support of the H beam (100).

And Figure 5 is an enlarged configuration diagram of the lower part of the H-beam 100 applied to the present invention, by connecting the H-beam pedestal 130 to the lower end of the H-beam 100 to prevent twisting of the H-beam 100 when transmitting impact energy Is done.

In addition, FIG. 6 is a front view showing the H beam 100 and the H beam support 130 applied to the present invention, and FIG. 7 is a side view showing the H beam 100 and the H beam support 130 applied to the present invention.

In addition, FIG. 8 is an exploded perspective view showing the H-beam 100 and the H-beam pedestal 130 applied to the present invention, and the technical effects of the present invention described above will be described in more detail below.

First, in the present invention, by inserting the anchor 150 into the fastening hole 131, the H beam support 130 is firmly fixed and installed on the concrete foundation in the ground.

After that, the H-beam 100 is vertically mounted on the upper end of the H-beam pedestal 130 and fixedly installed.

That is, the lower end of the H-beam 100 is positioned between the flow preventing portion 134 and the flow preventing portion 134, and the reinforcing portions 120 provided on both sides of the H-beam have a flange 132 and a flange After placing it between the 132, the H-beam 100 is fixedly installed by inserting it into the fastening hole 121 of the reinforcing part 120 and the fastening hole 133 of the flange 132 with bolts, but the bolts are reinforced on both sides. The H-beam 100 and the H-beam pedestal 130 are firmly fixed to each other by being inserted into the fastening hole of the negative fastening hole and the intermediate H beam.

At this time, a rubber plate 137 that absorbs shock is provided on the side of the flow prevention part 134 to closely contact the H beam 100 and protect the H beam 100 and the flow prevention part 134 from colliding with each other. To be able to do it.

The flow prevention part 134 applied to the present invention can be installed and used at either one or both ends of the upper end of the H-beam support 130.

In the present invention, when the shackle 145 is connected to the shackle connecting portion 135 formed inside the flow preventing portion 134, the net 140 and the wire rope 115 can be connected to each other.

That is, if the shackle 145 is inserted into the fastening hole 136 of the flow preventing part 134 and assembled, the net 140 and the wire rope 115 can be simply connected and used.

As described above, the H-beam 100, which is vertical to the top of the H-beam pedestal 131, uses a wire rope 115, etc., to the shock absorber 110 by using a bolt 113 and a shackle 145. Will decrease.

In other words, after placing the wire rope 115 in the upper mounting groove 111 of the H beam 100 so that it can flow, the bolt 113 is fastened to the fastening hole 112 through the side surface, and then the nut 114 is used. When tightened, it is possible to simply prevent the wire rope 115 from being separated.

At this time, the wire rope 115 is connected to the net 140 using a shackle 145 and the like.

In the above-described state, a wire rope 115 is connected to the bracket 116 formed at the upper edge of the shock absorbing unit 110 to further secure the supporting force of the H beam 100.

That is, after inserting the shackle 145 into the fastening hole 117 of the bracket 116, the wire rope 115 is connected to the shackle 145. At this time, the front end of the wire rope 115 is connected to the anchor 150, and the anchor 150 is driven into the ground or the concrete foundation in the ground to support the wire rope 115 in tension, resulting in the H beam 100 Will secure the support of

Therefore, the present invention as described above enables the impact energy that acts when earth and stone flows, pollutants, and rocks to flow into the high-tensile rockfall prevention measures, so that the impact absorbing unit 110 provided at the top of the H beam 100 attenuates the impact energy. In addition, the H-beam pedestal 130 provided at the lower end of the H-beam 100 is designed to support the lower end of the H-beam so that distortion does not occur.

In addition, the present invention allows the energy transmitted to the wire rope 115 to pull the wire rope downward when a local impact occurs and to reduce the energy transmitted to the H beam 10.

In addition, the present invention is to reduce the energy applied to the end of the wire rope 115 when secondary energy is generated by transferring energy to the side H beam.

In addition, in the present invention, the impact energy that acts when earth and stone flows, pollutants, and rock rocks flow into the high-tensile rockfall prevention measures is primarily attenuated by the elastic deformation of the net 140, and the remaining impact energy is transmitted to the wire rope 115. I did it.

In addition, in the present invention, the impact energy transmitted to the wire rope 115 is secondarily attenuated by the wire rope and net ring deformation and frictional resistance, and the residual impact energy is transmitted to the anchor 150.

In addition, the present invention is to prevent the H beam from being damaged by providing an impact absorbing unit 110 on the upper end of the H beam 100 so that energy is not transmitted to the end as it is during a primary impact such as a rockfall.

In addition, according to the present invention, when the reinforcing part 120 provided at the lower end of the H beam 100 and the H beam pedestal 130 are mutually assembled, even if impact energy is generated, distortion does not occur, so that the strength of the H beam can be maintained. I tried to connect.

The technical idea of the high-tensile rockfall prevention measure of the present invention is that it is possible to repeatedly implement the same results in practice. In particular, by implementing the present invention, it is possible to contribute to industrial development by promoting technological development, and thus it is worth protecting.

<Explanation of symbols for major parts of drawings>
100: H beam
110: shock absorber
115: wire rope
120: reinforcement
130: H beam support
140: net
150: anchor

Claims (5)

An H-beam support 130 that is fixedly installed using a plurality of anchors 150 on the natural ground or concrete foundation, and prevents twisting of the H-beam 100;
H beam 100 that is assembled and installed on the top of the H beam support 130;
An impact absorbing unit 110 provided at the upper end of the H-beam 100 and for attenuating impact energy that acts when earth and stone flows, foreign matters, and rockfalls enter the high-tensile rockfall prevention measures; And
Using the elastic deformation of the circular and high-strength net 140 fastened to the wire rope 115 connected between the H-beam 100 and the H-beam 100 in a state in which a plurality of H-beams 100 are installed at regular intervals. The impact energy is firstly reduced, and the anchor 150 is a high-tensile rockfall prevention measure, characterized in that the impact energy is secondarily reduced by the frictional resistance of the high-strength steel wire (wire rope) having ductility.
The method according to claim 1,
The H beam pedestal 130,
A plurality of fastening holes 131 formed at regular intervals so that the anchor 150 is fastened;
At least one flange 132 protruding from the upper end of the H-beam pedestal 130 and having a fastening hole 133 formed thereon so as to be assembled by bolts to the H-beam 100; And
High-tensile rockfall prevention measures, characterized in that it includes; is formed protruding from one or both ends of the upper end of the H-beam support 130, and prevents the movement and separation of the H-beam 100.
The method according to claim 1,
The shock absorbing unit 110,
A seating groove 111 having a concave groove so that the wire rope 115 is located in the center of the upper end; And
At least one bolt 113 that is horizontally fastened to the side fastening hole 112 of the H beam 100 and the mounting groove 111 to prevent the wire rope 115 from detaching; a high-tension rockfall prevention measure comprising a .
The method according to claim 1 or 3,
On either side or both sides of the shock absorbing unit 110,
At least one bracket 116 for connecting the wire rope 115 by fastening the shackle 145 to the fastening hole 117; a high-tensile rockfall prevention measure, characterized in that it further comprises.
The method according to claim 2,
On the side of the flow prevention part 134,
While closely contacting the H beam 100, a rubber plate 137 for protecting the H beam 100 and the flow preventing unit 134 from colliding with each other and absorbing the impact; a high-tensile rockfall prevention measure, characterized in that it further includes.

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