KR100513136B1 - Rock slope reinforcement structure and construction method thereof - Google Patents

Abstract

The present invention relates to a method of protective reinforcement of rock slopes in order to prevent the rock slopes from collapsing or falling rocks.

By stabilizing an unstable rock slope, the present invention fundamentally prevents the collapse of the slope and effectively prevents the risk of small scale collapse or rockfall due to the jointing of the surface, and at the same time, the surface can be recorded in appearance. In order to achieve the stability and environmental friendliness of the reinforcement at the same time, the present invention for this purpose in the reinforcement structure for reinforcing the slope of the rock, the predetermined surface toward the ground from the surface of the rock reflection surface Multiple rock bolts embedded in depth; A rear frame fixed to an exposed head of the lock bolt and formed by assembling a plurality of pipe members in a lattice shape; A vegetation wall that is installed to be spaced apart from the rear frame by a predetermined interval and is formed by stacking a plurality of vegetation bags in layers; Backfilled soil filled in the space between the vegetation wall and the rock slope; Provides a rock reflection surface reinforcement structure comprising a; geogrid is fixed to the rear frame and is installed to surround the outside of the front surface over the top and bottom of the vegetation wall.

Description

Rock Slope Reinforcement Structure and Construction Method Thereof}

The present invention relates to a method of protecting and reinforcing rock slopes in order to prevent the rock slopes from collapsing or falling down, and more particularly, by stabilizing unstable rock slopes to fundamentally block the collapse of the slopes as well as jointing of the surface. The present invention relates to a rock slope reinforcement structure that can effectively prevent the risk of small scale collapse and rockfall, and can also surface the surface in appearance, and at the same time achieve stability of the reinforcement and environmental friendliness. .

In general, in the case of opening roads, railways, etc. in mountainous terrain, or creating complexes, the mountain slope is cut off by a method such as blasting to secure a space in which roads or complexes can be formed. As a result of such civil construction, the side slopes exist as sloped slopes having a predetermined inclination angle.

In the case of the inclined slope as described above, if left untreated without any reinforcement measures, the ground may be weakened due to various natural disasters such as heavy rain or earthquake, which may cause phenomena such as falling rocks and earth and sand loss. There is a risk of a catastrophic event. Therefore, in order to prevent such damage due to the collapse of the slope in advance, various types of protection and reinforcement methods are generally performed on the inclined surface as described above.

Among the slope stabilization methods described above, in the case where the base surface is made of rock, the most common form of reinforcement is a method using a rock bolt. This rock bolt method drills a plurality of insertion holes at depths of 3 to 5 m or more at regular intervals on a rock surface where there is a risk of collapse, and inserts a member such as a deformed steel bar as a lock bolt into the insertion hole and then mortars them. It is fixed by grouting the back, and when a bearing plate having a certain thickness and stiffness is fitted to the exposed head of the fixed lock bolt, the nut coupled with the lock bolt is subsequently tightened. As the pressure plate is in close contact with the rock slopes, the ground is restrained and the support for the ground collapse can be made by the support ability of the rock itself.

However, in the case of the rock bolt method as described above, it is relatively effective against the overall collapse of the ground, but since this method is to install the rock bolt at a certain position of the rock as described above the rock between the rock bolt and rock bolt In the case of this, there was a problem of falling from the ground due to weathering, such as falling down and small scale collapse. In particular, this phenomenon is caused by vibrations, such as blasting during rock construction or civil engineering, where joints are highly developed. It can be said that there is a high risk in the case of ground disturbed surface.

Therefore, in order to prevent such risks, a method that tries to prevent small collapse or falling rocks by completely covering the surface using shotcrete on the rock slope where rock bolt is installed or by covering the rock slope with the entire rock slope. This was being implemented. However, the shotcrete method is excellent in terms of the stability of the surface layer of the sloped surface. However, the sloped surface to which the shotcrete method is applied is incapable of vegetation and is unsightly in appearance. There was a disadvantage to inhibit. In addition, in the case of the method by the rockfall prevention net, it is difficult to block the falling of the rock of relatively small size between the eyelids, so it is not a fundamental way to prevent the rockfall, and the damage caused by the aging of the net with age It occurred and needed periodic maintenance, and there was a disadvantage that the rock surface is visually exposed and not good in appearance.

Therefore, the present invention was devised to improve the general problems of the conventional rock slope reinforcement method as described above, the present invention fundamentally blocks the collapse of the slope by the rock bolt, as well as to be generated in such a rock bolt method It is possible to effectively prevent the risk of small scale collapse and falling rocks, and to surface the surface in terms of its appearance, thereby providing a rock slope reinforcement structure that can simultaneously achieve stability and environmental friendliness of reinforcement. It is the technical problem to do it.

In order to achieve the above technical problem, the present invention provides a new type of rock slope reinforcement structure improved from the prior art, which is a reinforcing structure for reinforcing a slope formed of a rock, from the surface of the rock slope to the ground. A plurality of rock bolts embedded in a predetermined depth; A rear frame fixed to an exposed head of the lock bolt and formed by assembling a plurality of pipe members in a lattice shape; A vegetation wall that is installed to be spaced apart from the rear frame by a predetermined interval and is formed by stacking a plurality of vegetation bags in layers; Backfilled soil filled in the space between the vegetation wall and the rock slope; The geogrid is fixed to the rear frame and is installed to surround the outer surface over the top and bottom of the vegetation wall; is characterized in that the rock reflection surface reinforcement structure comprising a configuration.

At this time, the geogrid is preferably to be bound to the rear frame at a predetermined height, that is, a height corresponding to the predetermined number of stages in which the vegetation bag is stacked, and in the case where the rear frame is fixed to the rock bolt, It is more preferable in view of convenience and economy of construction to couple the two pressure plate to the exposed head portion, but to fix the back frame to be in close contact between the two pressure plate.

Hereinafter, with reference to the accompanying drawings will be described in more detail the configuration and operation of the present invention with a preferred embodiment of the present invention.

1 is a cross-sectional view showing a rock reflection surface reinforcement structure according to the present invention, the rock reflection surface reinforcement structure according to the present invention as shown in the figure is a predetermined depth toward the ground from the surface of the rock reflection surface (R) as a whole A plurality of rock bolts 10 embedded with; A rear frame 20 fixed to the exposed head 12 of the lock bolt 10 and assembled by assembling a plurality of pipe members in a lattice shape; A vegetation wall 30 which is installed to be spaced apart from the rear frame 20 by a predetermined interval and is formed by stacking a plurality of vegetation bags 35; A backfilled soil 40 filled in the space between the vegetation wall 30 and the rock reflection surface R; And a geogrid 50 which is fixed to the rear frame 20 and is installed to cover the entire outer surface of the vegetation wall 30 over the top and bottom of the vegetation wall 30.

Among the components constituting the present invention, the lock bolt 10 corresponds to a rock bolt for rock slope reinforcement that has been commonly used in the prior art, which prevents the overall collapse of the rock slopes to be reinforced in the present invention. It is to play a role. As the construction of the rock bolt 10 is generally known, the insertion hole is drilled to a surface of the rock reflection surface R to a predetermined depth, and the rock bolt 10 is inserted into the insertion hole to grout by injecting mortar or the like. In this way, the head portion 12 of the protruding rock bolt 10 is fitted with a pressure plate 15 of a predetermined size, and then tightened with a nut 16 to form a rock reflection surface R of the pressure plate 15. Soil reinforcement is to be made by the adhesion to the. At this time, the length of the head portion 12 exposed to the outside of the lock bolt 10 should be as secured to 50 cm or more as possible to easily secure the rear frame 20 to be described later, the lock bolt ( The length and the spacing of 10 should be appropriately determined in consideration of the depth of the hair and the required strength.

The rear frame 20 is configured to form a lattice as a whole by a plurality of vertical members 22 and horizontal bands 24 by assembling a plurality of pipe members vertically and horizontally. The rear frame 20 basically serves as a base member capable of fixing the geogrid 50 in installing the geogrid 50, which will be described later. At the same time, the rear frame is a rock reflection surface (R). By connecting a plurality of rock bolts 10 scattered at a certain distance on the body integrally with each other to enable them to work together, the ground reinforcing effect is further enhanced.

There is no particular limitation in the method of fixing the rear frame 20 to the head 12 of the lock bolt 10, and depending on the site situation, such as by welding or using a separate bracket Or various methods such as binding with an iron wire may be considered. Meanwhile, in the present embodiment, as a method for fixing the back frame 20 to the lock bolt 10, two pressure plate 15 coupled to the lock bolt 10 is provided on the back surface between the two pressure plate. The vertical member 22 of the frame 20 is proposed to be fitted and fixed, and details thereof are shown in FIG. 2.

That is, in installing the pressure plate 15 under the conventional rock bolt construction method, it is common to use one pressure plate as a means for transmitting the tensile force of the rock bolt to the rock reflecting surface. As described above, one pressure plate 15b is additionally used in addition to the normal pressure plate 15a in contact with the rock reflection surface, and the vertical member 22 of the rear frame 20 is interposed between the pair of pressure plates 15a and 15b. By fastening and tightening the nut 16 in the positioned state, it is possible to prevent the rear frame 20 from being separated from the lock bolt 10. According to such a method, the construction can be made simply by the addition of a simple nut fastening operation, which can be said to be efficient in terms of construction convenience and economic efficiency. Therefore, the present invention proposes the above method as a preferable method for the installation of the rear frame. .

On the other hand, as the pipe member used in constructing the back frame 20 as described above, a suitable standard can be used in consideration of the situation of the site, and in the cross-sectional shape, a suitable one such as a round or square pipe can be selected and used as necessary. Can be. In this embodiment, as the vertical member 22, as shown in FIG. 2, a square bolt of 100 * 75 standard per one lock bolt 10 is used in one pair, and a horizontal band 24 is coupled thereto. Round galvanized steel pipes of Φ50 or more (can be replaced by general scaffolding pipes). At this time, the U bolt may be suitably used as a coupler of the vertical member 22 and the horizontal strip 24.

Outside the rear frame 20, the vegetation wall 30 for plant vegetation is installed upright. The vegetation wall 30 is located in the rock reflection surface reinforcement structure of the present invention and is exposed to the outside line of sight, which is achieved by stacking a plurality of vegetation bags 35 in a block manner. Vegetation bag constituting the vegetation wall 30 is to fill the soil and fertilizer and the like with vegetation seeds in a sack of a certain size, such a vegetation bag is a conventionally known and used, so a detailed description thereof will be omitted.

The vegetation wall 30 is installed spaced apart from the rear frame 20 and the rock reflection surface (R) at a predetermined distance, and in the space formed between the vegetation wall 30 and the rock reflection surface (R) installed in this way backfilled soil 40 is filled. The backfilled soil 40 is filled on the rear surface of the vegetation wall 30 to uniformly cover the entire surface of the rock reflection surface R to prevent rock and the like from falling off from the rock surface. It has a role as a kind of buffer layer for transmitting the pressure from the rock reflection surface (R) generated due to collapse, etc. to the geogrid 50 to be described later.

Furthermore, the present invention can also expect the effect of preventing the collapse of rock slopes and the occurrence of rockfall by delaying the weathering action of the rock surface by employing the configuration of the backfill soil 40 and the vegetation wall 30 as described above have. In other words, one of the main factors in weathering in the rock is to accelerate the cracking and weakening of the rock surface by freezing and expanding water in winter such as rainwater or groundwater that has penetrated into the joint surface created on the rock surface. In the case of the present invention, such a structure of the backfilled soil, etc., acts as an insulating thermal insulation layer, thereby significantly reducing the fear of freezing and expansion as described above. On the other hand, in the construction of the back-filled soil 40 can be compactly compacted by using compaction equipment such as a compactor (filler) after filling the high quality soil between the vegetation wall 30 and the rock reflection surface (R). In this case, the thickness of the backfill soil layer 40 is approximately 40 cm is appropriate.

Next, the geogrid 50 refers to a geotextile of the net form used for the purpose of ground reinforcement, ground treatment, etc. in various civil works, geogrid 50 used in the present invention also geogrid (geogrid) of this general type (geogrid) Is equivalent to). The geogrid 50 is installed to cover the entire outer surface of the vegetation wall 30 above and below, as shown in FIG. 2, and due to this configuration, a small collapse or rockfall generated from the rock reflection surface R It is possible to effectively distribute the load by the back and the like. The geogrid 50 is not particularly concerned with the collapse and if only a simple rockfall is a problem of 200kN / m strength is sufficient, if the risk of collapse or if there is a risk of collapse or a large amount of rock fall shearing Calculate and use the standard.

On the other hand, in installing the geogrid 50 as described above, if the height of the piled vegetation bag 35 is not high, it may be bound only to the upper and lower frames 20, but in most cases vegetation Since the number of stacked stages of the bag 35 will be formed at a considerable height or more, in such a case, as shown in the embodiment shown in FIG. 2, the geogrid 50 is placed on the back frame 20 at predetermined heights (about 4-5 stages of vegetation bag). ), It is preferable to prevent the vegetation wall 30 from being collapsed by the pressure due to collapse or falling rocks. At this time, in binding the geogrid 50 to the back frame 20, polyethylene (PE) string or bodkin may be suitably used.

Hereinafter, a method for constructing a rock reflection surface reinforcement structure of the present invention having the above configuration will be described in detail. 3 is a view showing an example of the construction of the rock slope reinforcement structure according to the present invention in order to explain the method of constructing the present invention with reference to the drawings.

(a) First, the rock bolts 10 are installed on the surface of the rock reflection surface at regular intervals. At this time, in installing the lock bolt 10 in order to be easily coupled to the rear frame so that the length exposed to the rock surface is 50cm or more. (See Fig. 3 (a).)

(b) When the construction work of the lock bolt 10 as described above is completed, the vertical member 22 of the rear frame is installed by fixing the pipe member to the exposed head of the lock bolt. As the vertical member 22, for example, as shown in Figure 2 can be configured by arranging two square pipes per one lock bolt (10), in the fixed installation of the shiatsu plate coupled to the lock bolt (10) In the manner of preventing the flow of the vertical member 22 by inserting another pressure plate (15b) to the lock bolt 10 in the state in which the vertical member 22 is mounted on the (15a) and then tighten the nut 16. It is preferable to follow. (See Fig. 3 (b).)

(c) When the installation of the vertical member 22 is completed as described above, the first end of the horizontal band 24 is installed by horizontally fixing the pipe member to the lower end of the vertical member 22. After the one-stage horizontal stripe 22-1 is provided in this manner, one end of the geogrid 50 is fixed to the one-stage horizontal stripe by using a PE string or vodkin. (See Fig. 3 (c).)

(d) Next, the vegetation wall 30 is formed by stacking vegetation bags on top of the fixed geogrid. At this time, the stacked stages of the vegetation bag 35 is preferably stacked about 4 stages. (See Fig. 3 (d).)

(e) Next, the back side of the vegetation bag 35 stacked as described above is backfilled using high quality soil, and compactly compacted using compaction equipment such as a compactor. (See Fig. 3 (e).)

(f) When the vegetation bags 35 are stacked at a predetermined height according to the above-described process, and the backfill soil 40 is formed, the geogrid 50, which has been fixed to the first stage horizontal band 22-1, is wound up. By raising and wrapping the outer side of the laminated vegetation bag 35 in close contact, and with the second stage horizontal band (22-2) is fixedly installed on the vertical member 22, and then the horizontal band The geogrid 50 is fixed by binding. (See Fig. 3 (f).)

(g) thereafter, after the steps (d) to (f) described above, that is, the vegetation bag 35 is stacked on the geogrid 50 at a predetermined height, and the backfill soil 40 is filled on the back, and then chopped. The geogrid 50 is wound up to repeatedly wrap the outer circumferential surface of the vegetation bag 35 to complete the entire rock slope reinforcement structure. (See Fig. 3 (g).)

Although the present invention has been described in detail with reference to the described embodiments, those skilled in the art to which the present invention pertains will be capable of various substitutions, additions and modifications without departing from the technical spirit described above. It is to be understood that such modified embodiments also fall within the protection scope of the present invention as defined by the appended claims below.

According to the present invention described in detail as described above it is possible to effectively prevent the collapse of the slope by the rock bolt as well as to effectively prevent the risk of small scale collapse or rockfall that can occur in such a rock bolt method, In terms of appearance, the surface can be greened to provide an effect of providing a rock reflection surface reinforcement structure capable of achieving stability of the reinforcement and environmental friendliness at the same time.

1 is a cross-sectional view showing a rock reflection surface reinforcement structure according to the present invention.

Figure 2 is a detailed view of the back frame in the present invention.

Figure 3 is a view showing an example in order to construct a rock reflection surface reinforcement structure according to the present invention.

Explanation of symbols on the main parts of the drawings

10: rock bolt 12: rock bolt head

20: rear frame 22: rear frame vertical member

24: rear frame horizontal member 30: vegetation wall

35: vegetation bag 40: backfill soil

50: geogrid

Claims (4)

In the reinforcement structure for reinforcing the slope of the rock, A plurality of rock bolts embedded at a predetermined depth from the surface of the rock reflecting surface to the ground; A rear frame fixedly installed at an exposed head of the lock bolt and formed by assembling a plurality of pipe members in a lattice shape; A vegetation wall body which is installed to be spaced apart from the rear frame by a predetermined interval and is formed by stacking a plurality of vegetation bags; Backfilled soil filled in the space between the vegetation wall and the rock slope; And, A geogrid bound to the rear frame and installed to surround the entire outer surface of the vegetation wall up and down; Rock slope reinforcement structure comprising a. The rock slope reinforcement structure of claim 1, wherein the geogrid is bound to the rear frame at predetermined heights. The method of claim 1 or claim 2, wherein the exposed head portion of the rock bolt is coupled to each of the two pressure plate, the back frame is a rock reflection surface reinforcement structure, characterized in that the fixing is made by being located between the two pressure plate. As a method of constructing a reinforcement structure for reinforcing a slope of rock, (a) installing rock bolts on the surface of the rock reflecting surface at regular intervals; (b) installing a vertical member of the rear frame by fixing a plurality of pipe members vertically at regular intervals to the exposed head of the lock bolt; (c) horizontally fixing the pipe member to the lower end of the vertical member to install a one-stage horizontal band and fixing one end of the geogrid to the one-stage horizontal band; (d) stacking vegetation bags a predetermined number of times on top of the fixed geogrid; (e) filling and filling backfill soil between the stacked vegetation bags and the rock reflecting surface; (f) horizontally fixing a pipe member to the vertical member to install a horizontal band, and winding the geogrid upward to cover and wrap the outer surface of the stacked vegetation bags in close contact with each other. Securing to the band; (g) repeating steps (d) to (f) to complete the rock slope reinforcement structure; Construction method of rock slope reinforcement structure comprising a.