KR102244734B1 - Falling-stone preventioninstitution for roads - Google Patents

Abstract

The present invention is configured to include a rockfall prevention unit that is installed on the slope to prevent the forward movement of the rockfall, and the rockfall prevention unit is installed so that the lower end is buried in the slope, and a plurality of them are disposed to be spaced apart from each other along the horizontal direction of the slope. The support frames and a rockfall prevention net that interconnects the support frames so that rockfalls generated at the rear of the support frames do not fall to the front of the support frames, and one end is connected to the upper end of each of the support frames, and the other end is It provides a rockfall prevention facility, characterized in that it is configured to include a support cable that is fixed to the government and supports the support frames. According to the above, it is economical because the structure is simple and the cost required can be reduced, and it is possible to improve workability due to easy on-site installation work, as well as to effectively block and prevent falling rocks.

Description

Falling-stone preventioninstitution for roads}

The present invention relates to a rockfall prevention facility, and more particularly, to a rockfall prevention facility that is installed on a slope to minimize damage caused by rockfall.

In general, a rockfall prevention facility is a structure that is installed on an incision or steep slope due to road construction to prevent accidents due to landslides or collapses. Rockfall prevention facilities have various types of structures such as fences, nets, and retaining walls. Among them, the net-type protective net is a facility that catches rockfalls falling from incisions or slopes so that they do not fall to the road or fall into the vicinity of the road. It is a representative structure widely installed in a certain area of the slope.

As an example of the technology for such a rockfall prevention structure, Korean Patent Registration No. 10-0585817 is a soundproof wall installed on the slope of a railroad in which a post is installed on a concrete foundation installed along the edge of the railroad, and a rectangular soundproof panel is installed between the posts. As a combined rockfall prevention structure, hinge shafts are installed at the bottom of the left and right sides of the soundproof panel to be hinged to the post, and the tip of the bellows plate is used to absorb the shock caused by falling rocks from the slope located behind the soundproof panel through the soundproof panel. The soundproof panel is fixed to the left and right sides, and the rear end of the bellows plate is fixed to the post, and the bracket is installed in a cross shape on the rear of the post, and the cylinder tube of the shock absorber and the piston rod are clevised to the post and the bracket. A rock-fall prevention structure for both soundproofing walls installed on the slope of the railway, characterized in that a bracket is installed at the rear to limit the opening angle of the soundproof panel so that it is caught on the bracket when opened, and the upper end of the post is connected with a crossbar. have.

However, such a conventional rockfall prevention structure has a problem that the structure is complex, the economical efficiency is low due to an increase in cost, and the workability is deteriorated due to the complicated installation work in the field.

Korean Patent Registration No. 10-0585817

The present invention is economical because it has a simple structure and can reduce the cost required, and it is easy to install on-site to improve workability, as well as to provide a rockfall prevention facility that can effectively block and prevent rockfall. The purpose.

The present invention is configured to include a rockfall prevention unit installed on the slope to prevent the movement of rockfall, and the rockfall prevention unit is installed so that the lower end is buried in the slope, and a plurality of the rockfall prevention units are arranged to be spaced apart from each other along the horizontal direction of the slope. And a rockfall prevention net that interconnects the support frames so that rockfalls generated at the rear of the support frame do not fall to the front of the support frames, and one end is connected to the upper end of each of the support frames, and the other end Provides a rockfall prevention facility, characterized in that it is configured to include a support cable that is fixed to the underground fixing portion on the slope to support the support frames.

Here, the fixing part may be composed of an anchor installed inside the slope.

In this case, the anchor may be installed in an anchor hole drilled on the slope, and a filler for reinforcing ground may be filled in the anchor hole.

A plurality of the rockfall prevention units may be arranged to be spaced apart from each other in a plurality of layers along the slope.

In this case, it is preferable that the rockfall prevention units disposed in a plurality of layers along the slope are configured to increase the anchor depth at which the support frame is buried as the lower layer with respect to the slope increases.

In addition, the support cable, one end is fixed to the upper end of any one of the support frames, the central portion is fixed to the upper end of the support frame located above the slope of the support frame to which the one end is fixed, and the other end May be fixed to the underground fixing portion above the slope of the support frame to which the central portion is fixed.

The rockfall prevention unit may connect the support frames in the same horizontal direction with one rockfall prevention net.

The rockfall prevention unit may further include a reinforcing wire installed in a transverse direction to interconnect the support frames in the same horizontal direction.

On the other hand, the rockfall prevention facility may be composed of a pair of rockfall prevention units that are arranged in the vertical direction on the slope and connected to each other by the support cable.

Here, the fixing part may be composed of a connection unit fixed to a lower end of the support frame provided in the upper layer buried in the ground.

At this time, the connection unit, a coupling member coupled to the lower portion of the support frame so as to be buried inside the slope, a connection cable having one end connected to the coupling member, and coupled to the other end of the connection cable, and the support cable It may be configured to include a connecting portion to be connected.

The connection part may be composed of a connection ring having a connection hole formed thereon, and the support cable may be configured by coupling a connection ring fitted to the connection ring to the other end.

The support frame may further include a support plate in which the support frame is fixed through the plate shape, and is positioned on the slope to support the slope so that the center of conduction of the support frame becomes the ground.

The rockfall prevention facility according to the present invention provides the following effects.

First, as it is installed on a slope, it is possible to effectively prevent the movement of rockfall, as well as to provide an economical effect because the structure is simple and the cost required can be reduced.

Second, since the existing anchor installed inside the slope can be applied, it is easy to install on-site and improve workability.

Third, the rockfall prevention unit can be arranged in multiple layers apart according to the slope situation, so that the target rockfall prevention effect can be obtained without design change, and the installation application is diverse and easy by varying the arrangement interval or number of arrangements. It can effectively block and prevent rockfall.

1 is a front view showing a rockfall prevention facility according to an embodiment of the present invention.
Figure 2 is a perspective view showing the rockfall prevention facility of Figure 1;
3 is a front view showing a case where a plurality of rockfall prevention units of FIG. 1 are spaced apart from each other in a plurality of layers along a slope.
4 is a front view showing another embodiment configured by extending the connection of the support cable of the rockfall prevention unit of FIG. 3 to a lower layer.
5 is a front view showing another embodiment in which the connection of the support cable of the rockfall prevention unit of FIG. 3 is different.
6 and 7 are front views showing a force acting upon the occurrence of a rockfall of the rockfall prevention unit of FIG. 5 and an action thereof.
8 is a view showing a case in which a support cable is connected by installing a connection unit to the rockfall prevention unit of FIG. 3.

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

First, referring to FIG. 1, a rockfall prevention facility according to an embodiment of the present invention includes a rockfall prevention unit installed on a slope to prevent the movement of rockfall.

Looking in detail with respect to such a rockfall prevention unit, the rockfall prevention unit is configured to include a support frame 100, a rockfall prevention net 200, and a support cable 300.

First, the support frame 100 is installed on the slope by being buried in the slope in the shape of a rod and erected in the longitudinal direction. At this time, the support frame 100 may be installed vertically with respect to the ground as shown, but this is an embodiment, which is installed inclined to the right with respect to the ground in consideration that the support frame 100 is inclined forward due to a rockfall. Of course you can.

On the other hand, the rockfall prevention unit, as shown in Fig. 2, a plurality of support frames 100 are arranged to be spaced apart from each other along the horizontal direction (row direction) of the slope to prevent falling rocks into the front use area. When the rockfall prevention net 200 is installed on the support frame 100 in the disposed state, the front use area is divided.

The rockfall prevention net 200 connects the support frames 100 to each other, and is formed of a mesh structure to block the movement of rockfalls generated in the rear of the support frames 100 to the use area in front of the support frames 100 Plays a role.

The rockfall prevention net 200 may be configured to connect the support frames 100 in the same horizontal direction made in one configuration as shown. However, this is an exemplary embodiment, and the rockfall prevention net 200 may be configured as a plurality of overlapping connections or may be connected to each other in various ways.

In addition, the rockfall prevention net 200, as shown, spreads from the upper end of the support frame 100 to the upper surface of the slope and is coupled to the support frame 100, but this is a preferred embodiment in the slope state and expected rockfall movement It goes without saying that it is possible to partially adjust the installation position of the support frame 100 such as the upper or lower part of the support frame 100 in consideration of the path or the like.

On the other hand, the rockfall prevention unit, although not shown, may be configured to include a reinforcing wire interconnecting the support frames 100 in the same horizontal direction.

The reinforcing wire is installed in the transverse direction to connect the support frames 100 in the horizontal direction to each other to prevent some of the support frames 100 from being separated when a rockfall occurs, and to reinforce the support force of the support frames 100 against rockfall. Plays a role.

Here, a plurality of reinforcing wires may be arranged and installed to be spaced apart along the longitudinal direction of the support frame 100 according to a required bearing capacity condition. In addition, the reinforcing wire is supported by various methods, such as winding the support frame 100 and binding it to the support frame 100, or being connected to the support frame 100 through a binding means such as a clamp, or joining through welding, etc. It may be combined with the frame 100.

Looking at the support cable 300, the support cable 300 is connected to each of the support frames 100 and serves to support the support frame 100.

In detail, the support cable 300 can be applied with a cable or wire, one end is connected to the upper end of each of the support frames 100, the other end is fixed to the rear slope of the support frame 100 (Fig. 1).

Here, one end of the support cable 300 may pass through the upper end of the support frame 100 and be connected to the support frame 100 through a fixing means, as shown, and the fixing means at this time is a known fixing bolt and Various configurations including nuts can be applied.

And the other end of the support cable 300 is fixed to the underground fixing portion 400 on the slope.

Here, the fixing part 400 is composed of an anchor 401 installed inside the slope, and the anchor 401 at this time can eliminate separate construction for anchor installation by applying a reinforcing ground anchor installed during the slope construction. have.

Meanwhile, the anchor 401 is installed in an anchor hole drilled on the slope, and at this time, the anchor hole may be filled with a ground reinforcing filler 550 to improve the supporting force of the support frame 100. Here, the ground reinforcement filler 550 may be a known ground reinforcement material such as concrete.

Referring to FIG. 3, the rockfall prevention units are arranged in a plurality of layers along the slope to be spaced apart from each other, so as to sequentially block rockfalls generated from the upper layers of the slope to reduce the impact of each rockfall prevention unit. It is configured to be. In this case, the rockfall prevention units may vary their installation positions in consideration of the slope of the slope, the environment, and the expected movement of the rockfall.

On the other hand, as described above, the rockfall prevention units arranged in a plurality of layers along the slope are preferably configured to increase the anchor depth at which the support frame 100 is buried toward the lower layer with respect to the slope.

This is because the energy of the rockfalls increases toward the bottom, so that the supporting force of the support frame 100 must be secured higher. Accordingly, the rockfall prevention units may more effectively prevent the movement of the rockfall by varying the anchor depth of the support frame 100 according to the installation height with respect to the slope as described above.

4 is a view in which the support cable 310 is connected to the support frame 100 in a different configuration. Referring to the drawings, the support cable 310 has one end fixed to the upper end of any one of the support frames 100, and the central part is on the upper slope of the support frame 100 with one end fixed. It is fixed to the upper end of the support frame 100 is located, the other end is configured to be fixed to the underground fixing portion 400 on the slope of the upper side of the support frame 100 with the central portion fixed.

That is, the support cables 310 are all connected and fixed to the front two support frames 100 adjacent to each other in the vertical direction on the sloped surface.

In this case, since the support frame 100 is prevented from being transferred forward by the underground fixing portion 400 and the upper support frame 100, a higher supporting force can be secured.

5 and 6 are views showing another embodiment of the rockfall prevention facility.

First, referring to Figure 5, the rockfall prevention facility according to another embodiment of the present invention is composed of a pair of rockfall prevention units arranged in the vertical direction on the slope, the pair of rockfall prevention units is a support cable (320 ) Are connected to each other.

In other words, in the above-described rockfall prevention facility, a pair of rockfall prevention units connected to each other by a support cable 320 are formed as a group unit and are installed on the slope, and these rockfall prevention facilities are group units depending on the environment of the slope or the length of the slope. A plurality of can be installed.

Looking at such a rockfall prevention facility, first, in the rockfall prevention facility, a pair of rockfall prevention units are connected to each other by a support cable 320, and a support cable 320 connected to the upper end of the support frame 100 located on the upper layer. ) Is fixed to the ground on the slope of the rear, and the support cable 320 connected to the upper end of the support frame 100 positioned on the lower layer is fixed to the lower end of the support frame 100 positioned on the upper layer.

At this time, the support cable 320 connected to the upper end of the support frame 100 of the lower layer, the other end is fixed to the lower end buried in the ground of the lower support frame 100 of the upper layer.

This is, when the upper layer support frame 100 is inverted (rotated), the upper part is resisted by the support cable 320 connected to the rear underground fixing part 400, and the lower part is connected to the front lower layer support frame 100. This is because conduction is resisted by the support cable 320, and an effect of increasing resistance to conduction can be obtained.

On the other hand, the fixed position of the lower end of the support frame 100 must be located below the rotation center when the support frame 100 is inverted to exhibit the effect of increasing the conduction resistance as described above.

However, when the support frame 100 is inverted, the center of rotation is fluidly changed depending on the state of the ground and the buried depth of the support frame 100.

Accordingly, in the present invention, in order to ensure that the center of rotation is formed on the ground of the slope when the support frame 100 is inverted, so that the fixed position of the lower end of the support frame 100 buried in the ground is always located below the center of rotation, It may be configured to include a support plate 540 coupled to the support frame 100.

The support plate 540 serves to enlarge the contact area of the support frame 100 with respect to the slope so that the center of rotation is formed on the ground of the slope when the support frame 100 is overturned.

Looking at such a support plate 540, the support plate 540 is formed in a plate shape so as to increase the contact area with respect to the slope as shown, is fixed through the support frame 100, and is fixed on the slope surface. It is located in and is configured to support the slope. Here, the configuration of the support plate 540 is configured in a plate shape so that manufacturing is easy and the contact area to the slope surface can be increased, but this is a variety of configurations if it can achieve the above purpose other than the plate shape shown as an embodiment. Can be applied.

Hereinafter, when a rockfall occurs, the conduction force acting on the rockfall prevention facility and its resistance will be described.

First, when a rockfall occurs from the top, as shown in FIG. 6, the rockfall prevention facility firstly causes the rockfall to fall to the top rockfall prevention unit, thereby generating a conduction resistance in the top rockfall prevention unit.

At this time, the upper layer support frame 100 uses the support plate 540 as a rotational center due to the rockfall at the rear, so that the upper part generates a force to be conducted downward (left in the drawing), and the lower part is also supported in response thereto. A force to rotate the plate 540 in the upper direction of the slope (right side in the drawing) is generated as the center of rotation.

Then, the support cable 320 connected to the lower end of the upper layer support frame 100 is pulled to the rear, and for this reason, the lower layer support frame 100 has the upper end of the slope by the support cable 320. It is subjected to a tensile force (right side in the drawing) to further increase the support force of the lower layer support frame 100.

On the other hand, in the case of a continuous landslide such as a landslide, rockfall does not occur only with the upper rockfall prevention unit of FIG. 6, and as shown in FIG. 7, rockfall occurs not only with the upper rockfall prevention unit but also with the lower rockfall prevention unit. Thus, a conduction resistance may be generated in each of the upper layer rockfall prevention unit and the lower layer rockfall prevention unit.

Looking at this, first, the upper layer rockfall prevention unit is configured to increase the conduction resistance of the lower layer rockfall prevention unit due to the rockfall, and the reason is as described above in FIG. 6.

If so, looking at the lower layer rockfall prevention unit, the lower layer support frame 100 receives force in the lower direction of the slope (in the direction of the left arrow in the drawing) due to the rockfall, and conduction is prevented by the support cable 320 connected to the upper end. Resistant tensile force is generated.

At this time, the support cable 320 connected to the upper end of the lower layer support frame 100 is pulled in the left direction as shown, and in this case, the upper layer support frame 100 has a lower end of the support plate 540 ) As the rotation center and the force to rotate in the lower direction of the slope (left direction in the drawing) is generated.

In this case, the upper layer support frame 100 generates a force to rotate the upper end of the slope upward (rightward direction in the drawing), thereby increasing the conduction resistance.

That is, in the upper layer support frame 100, when the lower layer support frame 100 is subjected to force due to a rockfall, the conduction resistance is increased by the support cable 320 connected to the lower layer support frame 100.

As described above, the rockfall prevention facility, by connecting the rockfall prevention unit in the upper layer and the rockfall prevention unit in the lower layer to each other through the support cable 320, so that the rockfall prevention unit in the upper layer and the rockfall prevention unit in the lower layer increase the conduction resistance to each other. By configuring to have a mutual relationship, the rockfall prevention effect can be improved as much as possible, and the rockfall can be effectively prevented even in various types of landslides.

Meanwhile, the support cable 320 connected to the upper end of the lower layer support cable 320 may be fixed by the fixing part 400 coupled to the lower end of the upper layer support frame 100.

Here, the fixing part 400 is composed of a connection unit 600 fixed to the lower end of the upper layer support frame 100 buried in the ground.

Referring to FIG. 8, the connection unit 600 includes a coupling member 610, a connection cable 620, and a connection part 621.

The coupling member 610 is coupled to the lower portion of the support frame 100 so as to be buried inside the slope. This is to ensure that the coupling position of the coupling member is located below the conduction center point of the support frame 100, and the detailed reason for this is as described above.

The coupling member 610 may be configured to surround the outer surface of the support frame 100 as shown, or may be coupled through the support frame 100, although not shown, and the support frame 100 is coupled and fixed. It can be applied in various ways as long as it is a configuration.

The connection cable 620 is configured such that one end is connected to the coupling member 610 in the ground, and the other end is exposed to the top of the slope so that the operator can check it from the outside.

The connection part 621 is coupled to the other end of the connection cable 620, and the support cable 320 is connected.

In the drawing, the connection part 621 is composed of a connection ring having a connection hole formed as shown, and the support cable 320 has a connection ring 531 coupled to the other end thereof, and the connection ring is connected to the connection ring. It is configured to fit and combine so that the operator can work more easily the connection of the support cable 320 in the field.

According to the above, the connection unit 600 is configured to allow the support cable 320 to be easily connected to the lower end buried in the ground of the upper layer support frame 100, and the operator connects the support cable 320 For this purpose, it is possible to easily connect to the lower end of the support frame 100 from the outside without digging the slope to the lower end of the support frame 100 buried in the ground.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those of ordinary skill in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100: support frame 200: rockfall prevention net
300,310,320: support cable 400: fixed part
401: anchor 531: connecting ring
540: support plate 550: filler
600: connection unit 610: coupling member
620: connection cable 621: connection part

Claims (2)

It includes a rockfall prevention unit that is installed on the slope and prevents the movement of rockfall,
The rockfall prevention unit,
A support frame installed such that a lower end portion is buried in the slope, and a plurality of support frames disposed to be spaced apart from each other along the horizontal direction of the slope;
A rockfall prevention net for interconnecting the support frames so that rocks generated at the rear of the support frame do not fall to the front of the support frames;
One end is connected to an upper end of each of the support frames, and the other end is fixed to the ground on the slope and comprises a support cable for supporting the support frames:
The rockfall prevention unit,
A plurality of them are arranged to be spaced apart from each other in a plurality of layers along the slope:
The support frame,
It is provided in the center of the support frame, is located on the buried ground, and is configured to include a support plate that becomes a center of rotation when the support frame is inverted, the lower part of the support plate is buried under the ground, and the upper part of the support plate is above the ground. Protruding:
The other end of the support cable,
It is fixed to the lower end of the support plate buried below the ground:
Fixing the other end of the support cable and the lower end of the support frame,
A connection unit coupled to a lower end of the support frame and an end portion of the support cable are coupled to each other;
The connection unit,
A coupling member coupled and fixed to the lower end of the support frame
One end is connected to the coupling member of the underground, the other end is a connection cable exposed to the outside of the slope,
It is coupled to the end of the connection cable, and comprises a connection portion formed in a ring shape so that the end of the support cable is coupled:
The rockfall prevention unit,
A rockfall prevention facility, characterized in that it comprises a reinforcing wire installed in a transverse direction and interconnecting the support frames in the same horizontal direction.
The method of claim 1,
Rockfall prevention units arranged in a plurality of layers along the slope,
A rockfall prevention facility, characterized in that the anchor depth at which the support frame is buried increases toward the lower layer with respect to the slope.

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