KR100858315B1 - Method of stabilization of slope using flowerbed and longitudinal type member for slope stabilization - Google Patents

Abstract

A revegetation method by forming a flower bed of environment-friendly slope stabilization is provided to reinforce and to revegetate a slope using the shape of a natural slope as it is, and a longitudinal member for slope stabilization is provided to be fixed to a slope strongly and to fix with a concrete flower bed strongly by using a longitudinal body for slope stabilization. A revegetation method by forming a flower bed of environment-friendly slope stabilization comprises the steps of: forming an insertion hole by perforating a slope(30) for stabilization; stabilizing a slope by inserting the bottom of a longitudinal body of a longitudinal member for slope stabilization to the insertion hole, filling up the insertion hole with filler, anchoring the bottom of the longitudinal body for slope stabilization and anchoring a first head anchorage(200) in the middle of the longitudinal body for slope stabilization; forming a concrete flower bed(40) by placing concrete between the slope and the longitudinal body for slope stabilization, and then curing the concrete; stabilizing the concrete flower bed by anchoring a second head anchorage(400) on the top of the longitudinal body for slope stabilization; and filling up an inside space of the concrete flower bed with vegetative soil. A longitudinal member for slope stabilization comprises a longitudinal body for slope stabilization composed of an anchorage inserted and fixed to an insertion hole of a slope and a head extended from the anchorage and exposed to the outside of the slope, and a head anchorage installed to the head of the longitudinal body for slope stabilization, wherein a first head anchorage fixed to the part intersecting the slope and a second head anchorage fixed to the top of the head are installed to the head respectively.

Description

METHOD OF STABILIZATION OF SLOPE USING FLOWERBED AND LONGITUDINAL TYPE MEMBER FOR SLOPE STABILIZATION}

The present invention relates to a construction method for stabilizing and recording the slope of the incision or nature, and to the slope-type length member for stabilization of the slope, specifically the slope-type length for slope stabilization, such as earth anchors, rock bolts, rebars Construction method to stabilize concrete flower bed by using slope stability length member used for stabilization of slope after again placing concrete directly by pouring concrete directly after stabilization by member, and slope stability length type that can be used for such construction method It is about absence.

The above-described and below stability member for slope stability means a member having a long length at which one end is fixed to the ground such as an earth anchor, a lock bolt, a rebar, and the like to stabilize the slope.

In Korea, where there are many forests, it is often necessary to cut slopes for the construction of roads and railways. If the slope of the inclined slope is steeper than the angle of inclination, reinforcement is necessary to prevent collapse. In addition, in the case of a cancer incision, there is a risk of an accident caused by a rockfall, so reinforcement is required. However, in recent years, along with the reinforcement according to the need of such stability, there is a need for environmentally friendly greening of slopes that can be combined with the surrounding environment and beautifully aesthetically enhanced.

Figure 1 is a side cross-sectional view showing a slope recorded by the conventional recording method of the sloped surface, Figure 2 is a side cross-sectional view showing a slope recorded by another conventional construction method.

In the prior art illustrated in FIGS. 1 and 2, the preliminary concrete block 10 is fixed to the slope by an earth anchor 12 or a lock bolt 14. Looking at the structure and construction order of these conventional methods of greening of the slopes, first, a block made of concrete is produced in advance. The concrete block 10 has a space therein, and has a drainage hole (not shown), etc. in the lower portion is produced in favor of vegetation. On the other hand, the concrete block 10 is formed so that the groove is formed to be fitted between the concrete blocks 10 are stacked in multiple stages.

In order to reinforce and stabilize the inclined surface by the prior art, first, the inclined inclined surface 20 is installed to install the earth anchor 12 or install the lock bolt 14. After that, the soil is deposited in a predetermined thickness.

Next, the above-described concrete block 10 is placed on the fill layer 22 and connected to the end of the earth anchor 12 or the rock bolt 14. And fill the backfill soil on the back of the concrete block (10). After the concrete block 10 is installed in the entire sloped surface in this manner, the vegetation soil is filled in the inner space of the concrete block 10 and the shrubs are planted.

As another method, when the fill layer 22 is not formed or the backfill soil is not to be used, the incised cut surface is cascaded again. At this time, the shape of the stairs to be cut is cut into a shape corresponding to the shape of the concrete block 10. After that, the drilled incision is cut to install the earth anchor 12 or the rock bolt 14 and the concrete block 10 is connected to it to be installed in a multi-layer.

Next, fill vegetation soil and plant shrubs as above.

However, the prior art as described above has the following problems.

1) In order for the concrete block to be stably supported on the slope, it is necessary to form a fill layer or cut the cut sheet to match the shape of the concrete block. In other words, there is a problem in that the concrete block can not be installed directly in the case of a rock incision. Therefore, additional construction costs are required.

2) In the prior art, when the concrete block is looked at the structure fixed to the earth anchor or rock bolt, one end of the concrete block is simply connected to the earth anchor or rock bolt (in the form of FIG. 2) or one end of the earth anchor or rock bolt is concrete After penetrating the block, such as the end of the earth anchor penetrating the concrete block is to be settled. (Figure 1)

As shown in FIG. 2, the structure in which the concrete block is simply connected and fixed to the earth anchor or the rock bolt is very fragile, and the concrete block may be separated from the earth anchor or the rock bolt when an unexpected concentrated load occurs.

As shown in FIG. 1, a structure in which one end of the earth anchor or rock bolt penetrates the concrete block and then the end of the earth anchor or the like that penetrates the concrete block is fixed there is a risk that the earth anchor or the lock bolt itself is separated from the ground. . In order to explain this problem, the technique will be described based on the earth anchor.

In the case of the earth anchor, it is generally composed of a fixing part, a free part and an anchor head. The fixing part is fixed to the ground to transmit necessary loads to the ground, the free part transmits a given load to the fixing part, and the anchor head is equipped with a head fixing part. The fixed load is fixed to maintain the load on the free part and the fixing part.

The tension member used for the free and anchoring parts of the earth anchor usually uses a PC strand or a steel bar.

In addition, in the structure of fixing the tension member, a wedge method mainly using wedge cone is used in the case of the strand, and a nut method is mainly used in the case of the steel rod.

In the construction of the earth anchor, the ground is drilled to a predetermined depth and diameter, the fixing part is inserted into the perforation portion, and the filling material (such as grout or cement paste) is filled. When a predetermined time elapses when the filler is hardened, the tension member is tensioned under a predetermined load to stabilize the anchor head by the head fixing unit.

The force on which the earth anchor is fixed to the ground is determined by the tension applied to the earth anchor.

Considering the construction method of the earth anchor and the fixed structure of the concrete block, when the head of the earth anchor is tensioned while being exposed to the outside through the concrete block, the concrete block is formed between the head and the slope of the earth anchor. Since it is located, it is not possible to increase the tension due to the problem of strength that the concrete block can withstand. That is, in the form as shown in FIG. 1, the maximum range of tensioning the earth anchors should be limited to the strength that the concrete block can withstand, and therefore, the force anchored in the limited range of the ground anchor is very weak. If the earth anchor is tensioned out of the limited range, the anchoring force between the earth anchor and the ground is strengthened, but there is a risk that the concrete block will be damaged during the tension.

The present invention has been made to solve the problems of the prior art as described above, to provide a construction method for reinforcing the slope and greening using the form of natural slope as it is.

In addition, the present invention is a new construction that can be firmly fixed to the slope slope length body for slope stabilization length body using the slope stability length body such as earth anchor, rock bolt, reinforcing bar, etc. To provide a method and a longitudinal member for slope stabilization therefor.

The present invention to solve the above problems, the insertion hole forming step of forming an insertion hole by drilling a slope to be stabilized; Inserting the lower end of the slope-stable length-type body into the insertion hole and filling the filler in the insertion hole to fix the lower end of the slope-stable length-type body and to mount the first head fixing portion in the middle of the slope-stable length-type body A slope stabilization step of stabilizing the slope; Flower bed composition step of forming a concrete flower bed by placing and curing concrete between the slope and the upper end of the slope-shaped longitudinal body; A flower bed stabilizing step of stabilizing the concrete flower bed by mounting a second head fixing part on an upper end of the slope type length body; A vegetation soil filling step of filling vegetation soil in the interior space of the concrete flower bed; Characterized in that comprises a.

In the above, after the slope stabilization step, the pressure transmission tube is mounted on the slope-stabilizing length-shaped body above the first head fixing unit, and in the flower bed stabilizing step, the second head fixing unit includes the second head fixing unit. Preferably, the pressure transmission tube is mounted while applying pressure to the first head fixing unit.

According to another aspect of the present invention, a longitudinal stabilization length body comprising a fixing part inserted into and fixed to an insertion hole of a slope and a head extending from the fixing part to be exposed to the outside of the slope, and the head of the longitudinal stabilizing length body. A longitudinal stabilizing member comprising a head fixing part mounted to a head, wherein the head is equipped with a first head fixing part mounted at a portion crossing the slope and a second head fixing part mounted at an upper end of the head. It features.

In the above, it is preferable that a pressure transmitting tube is mounted to the head, one end of the pressure transmitting tube is in contact with the first head fixing unit, and the other end is in contact with the second head fixing unit.

In the above, the first head fixing unit is provided with a pressure plate formed with a through hole through which the longitudinal body for slope stabilization penetrates in the center, and a wedgecon fastening portion provided at an upper portion of the pressure plate and through which the slope stabilized longitudinal body penetrates. Fixtures having male threads formed on the outer circumferential surface, wedge cones mounted on the wedge cone fastening unit to fix the slope-shaped body for fixing the slope, wedge cone fixing plates provided on the wedge cones, and contact with the wedge cone fixing plates. And a nut member comprising a top plate having a stable length-type body through-hole and a tubular body having a female thread thread formed therein and extending from the edge of the top plate to a male thread of the anchorage on an inner circumferential surface thereof. One end is preferably in contact with the upper plate of the nut member.

The present invention as described above, it is possible to provide a construction method to reinforce the slope and greening using the form of the natural slope as it is.

In addition, the present invention is a new construction that can be firmly fixed to the slope slope length body for slope stabilization length body using the slope stability length body such as earth anchor, rock bolt, reinforcing bar, etc. A method and a longitudinal member for slope stabilization can be provided.

Hereinafter, a method of stabilizing slopes and constructing flower beds according to a first embodiment of the present invention will be described.

In this embodiment, an earth anchor provided with a stranded wire as a tension member was used as the longitudinal body for slope stabilization. However, according to the embodiment, an earth anchor with a steel rod as a tension member, or rock bolts, rebars, or the like may be used as the length body for slope stabilization.

3A to 3F are construction sequence diagrams showing a construction method for stabilizing and recording a slope according to the first embodiment, FIG. 4 is a side cross-sectional view of a flower bed site constructed by FIGS. 3A to 3F, and FIG. 3A to 3F are side cross-sectional views showing a state in which the slope is stabilized and greened.

Figure 3a is the insertion hole forming step. First, the inclined surface 30 to be stabilized is formed to form the insertion hole 32.

3B is a slope stabilization step in which a slope is stabilized by an earth anchor. As shown in the drawing, the lower end of the earth anchor body 100 is inserted into the insertion hole 32 and the filling material 31 is filled into the insertion hole 32 to grout. In this case, the strand 110 forming the earth anchor body 100 protrudes a considerable length to the outside. Then, when the filler 31 is hardened, the first head fixing unit 200 is mounted on the anchor body 100, the strand wire 110 is tensioned by a predetermined force, and the strand wire 110 is fixed to the first head fixing unit 200. It is fixed by) to maintain the tension force to stabilize the slope.

The structure of the first head fixing unit 200 will be described in detail.

First, the pressure plate 210 in contact with the slope 30 is provided. The pressure plate 210 has a through hole 211 through which the strand 110 passes through. The pressure plate 210 allows the compressive force of the strand 110 to be evenly distributed on the slope 30.

The fixing unit 220 is provided on the pressure plate 210.

A wedgecon fastening portion 221 through which the strand 110 is penetrated is formed in the central portion of the fixing unit 220, and a male thread 222 is formed on the outer circumferential surface thereof.

The wedge cone 230 is mounted on the wedge cone fastening portion 221 of the fixing unit 220, and the wedge cone 230 fixes the strand wire 110.

The wedgecon fixing plate 240 is provided on the wedgecon 230. The wedge-con fixing plate 240 receives downward force from the upper portion, ie, the nut member 240, to apply downward force to the wedge cone 230, so that the wedge cone 230 is moved from the wedge cone fastening portion 221. This prevents the departure.

The nut member 250 is provided on the wedgecon fixing plate 240.

The nut member 250 consists of an upper plate 251 and a tubular body 252.

The upper plate 251 is provided at the upper portion of the wedge-con fixing plate 240 and is formed in the center of the length-type body for slope stabilization, specifically, the length-type body through-hole for stabilization through which the strand 110 is penetrated.

The tubular body 252 extends downward from the edge of the upper plate 251, and an internal thread 252a is formed on an inner circumferential surface of the tubular body 252, and the female thread 252a is an external thread of the anchorage 220. Screwed with (222).

That is, the nut member 250 is screwed to the fixing unit 220 while applying a downward force to the wedge cone 230 through the wedge cone fixing plate 240 so that the wedge cone 230 is from the wedge cone coupling portion 221. This prevents the departure.

In the above structure and action of the shiatsu plate 210, the fixing unit 220, the wedge cone 230 is the same as the structure and action of the conventional earth anchor. This structure is the same as the structure of the head fixing unit which is mounted on the head of the earth anchor in order to maintain the tension force after tensioning the conventional earth anchor. In addition, the structure alone can be used to tension the earth anchor with a strong force to ensure that the earth anchor is fixed to the slope.

The wedge-con fixing plate 240 and the nut member 250 prevent the wedge-con 230 from being separated from the wedge-con fastening part 221 when the tension line 110 is tensioned again after the concrete flower bed 40 is formed. It is to.

FIG. 3C illustrates a state in which the pressure transmission pipe 300 is mounted after the slope stabilization step of FIG. 3B.

The pressure transmission pipe 300 is mounted on the strand wire 110 so that the strand wire 110 penetrates the inside of the pressure transmission pipe 300.

As a result, the lower end of the pressure transmission tube 300 comes into contact with an upper portion of the first head fixing unit 200, specifically, an upper portion of the nut member 250.

3d is a state in which the concrete flower bed 40 is formed after mounting the pressure transmitting pipe 300 as shown in FIG. 3c.

The concrete flower bed 40 is formed between the upper end of the strand wire 110 and the inclined surface 30, and thus, even when the concrete flower bed 40 is formed, the upper end of the strand wire 110 is exposed to the outside of the concrete flower bed 40. .

The concrete flower bed 40 is formed by constructing the formwork and the reinforcing bars inside the formwork, as in the usual construction method of the concrete structure, and then removing the formwork through a curing period for some time after pouring concrete in the formwork.

Thus, by using the concrete flower bed 40 by site casting, the form of a natural slope can be utilized as it is.

3E is a flower bed stabilization step in which a concrete flower bed is stabilized by an earth anchor.

As shown, the second head fixing unit 400 is mounted on the strand wire 110 to the strand wire 110 protruding out of the concrete flower bed 40, and the tension wire 110 is tensioned by a predetermined force and the strand wire ( 110 is fixed by the second head fixing unit 400 to maintain the tension force concrete bed 40 is stabilized.

In this case, the tension force for tensioning the strand 110 in FIG. 3E should be about 5% to 20% of the tensile force applied to the strand 110 in FIG. 3B. The tension of the strand 110 in FIG. 3b was for the earth anchor body 100 to be strongly secured to the slope, whereas in FIG. 3e the concrete flower bed 40 was relatively to the earth anchor body 100 compared to FIG. 3b. This is because it is intended to be fixed by weak force. In addition, the tension applied to the strand 110 in Figure 3e should be performed within the limit of the strength that the concrete flower bed 40 can withstand.

The structure of the second head fixing unit 400 will be described in detail.

First, the pressure plate 410 in contact with the concrete flower bed 40 is provided. The pressure plate 410 has a through hole 411 through which the strand 110 passes through. The pressure plate 410 is to ensure that the compressive force of the strand 110 is evenly distributed in the concrete flower bed (40).

The fixing unit 420 is provided on the pressure plate 410.

The wedgecon fastening part 421 through which the stranded wire 110 penetrates is formed in the center part of the fixing unit 420.

The wedge cone 430 is mounted on the wedge cone fastening portion 421 of the fixing unit 420, so that the wedge cone 430 fixes the strand wire 110.

The structure and function of the pressure plate 410, the fixing unit 420, the wedge cone 430 as described above is the same as the structure and operation of the conventional earth anchor.

On the other hand, the second head fixing unit 400, specifically, the lower portion of the fixing unit 420 is provided to contact the upper end of the pressure transmission pipe 300.

Therefore, when the tension wire 110 is tensioned while applying the downward force to the anchorage 420 when the tension wire 110 is tensioned in FIG. 3E, the anchorage 420 passes through the pressure transmission pipe 300 and the first head anchorage part. Downward pressure is applied to the (200). This is to prevent the first head fixing unit 200 from receiving the upward force when the tension wire 110 is tensioned in FIG. 3E or the wedge cone 230 is separated from the wedge cone fastening unit 221.

Therefore, the tension of the strand 110 in FIG. 3e does not affect the tension applied to the lower portion of the first head anchorage 200, whereby the tension generated in the strand 110 causes the first head anchorage 200. As a reference, it is divided into a tension force for fixing the slope of the lower portion and a tension force for fixing the concrete flower bed 40 of the upper portion.

Accordingly, the earth anchor body 100 stabilizes the slope 30 by a first compression force acting between the lower end of the earth anchor body 100 and the first head fixing unit 200, and the first head fixing unit 200. ) And the concrete flower bed 40 is stabilized by the second compression force acting between the second head fixing unit 400.

At this time, the second compressive force is about 5% to 20% of the first compressive force, which stabilizes the slope 30 very firmly, and the second compressive force is an appropriate force necessary to fix the concrete flower bed 40. Stabilize the concrete flower bed 40 (that is, a force within the strength range that the concrete flower bed can withstand).

Figure 3f shows the vegetation soil filling step of filling the vegetation soil in the inner space of the flower bed.

In FIG. 3E, the vegetation soil 41 is filled in the stabilized concrete flower bed 40, and a shrub 42 having a relatively small size is planted therein. It is preferable to form a drainage layer 43 or the like below the vegetation soil 41 to favor the vegetation.

By repeating the above steps to reinforce and green the entire slope can achieve the slope as shown in FIG.

6 is a side sectional view of a second embodiment according to the present invention, corresponding to FIG. 4 as the first embodiment.

In the second embodiment, the rest of the structure is the same except that the lock bolt 100a is used instead of the earth anchor as the length type body for slope stabilization. The rock bolt 100a of this embodiment is a rock bolt of a reinforcing bar shape.

The above embodiments are merely preferred embodiments of the present invention, and the technical spirit of the present invention may be variously modified or adjusted by those skilled in the art. Such modifications and adjustments fall within the scope of the present invention if they use the technical idea of the present invention.

The present invention can be used as a construction method for stabilizing and greening inclined surfaces or natural slopes, and as a longitudinal member for slope stabilization for stabilization of such slopes.

Figure 1 is a side cross-sectional view showing a slope recorded by the conventional recording method of the sloped surface, Figure 2 is a side cross-sectional view showing a slope recorded by another conventional construction method.

3A to 3F are construction sequence diagrams showing a construction method of stabilizing and recording a slope according to the first embodiment, FIG. 4 is a side cross-sectional view of a flower bed site constructed by FIGS. 3A to 3F, and FIG. 3A to 3F are side cross-sectional views showing a state in which the slope is stabilized and greened.

6 is a side sectional view of a second embodiment according to the present invention, corresponding to FIG. 4 as the first embodiment.

<Description of Symbols for Main Parts of Drawings>

30: slope side 31: filler

32: insertion hole

40: concrete flower bed

200: first head fixing unit 210: pressure plate

220: anchorage 230: wedge cone

240: wedge cone fixing plate 250: nut member

300: pressure transmission pipe

400: second head fixing unit

Claims (7)

An insertion hole forming step of forming an insertion hole by drilling a slope to be stabilized; Inserting the lower end of the slope-shaped longitudinal body into the insertion hole and filling the filler in the insertion hole to fix the lower end of the slope-stabilized longitudinal body, and in the middle of the slope-stabilized longitudinal body, the slope stabilization length in the center A pressure plate having a through-hole through which the die body penetrates, a wedge-cone fastening portion provided at an upper portion of the acupressure plate, through which the length-shaped body for slope stabilization is formed, and a fixing unit having a male thread formed on an outer circumferential surface thereof, and mounted on the wedge-cone coupling portion. Wedge cone for fixing the longitudinal body for stabilizing the slope, the wedge cone fixing plate provided on the upper portion of the wedge cone, the upper plate formed in contact with the wedge cone fixing plate and the longitudinal body through hole for slope stabilization and from the edge of the top plate to the bottom Extends and is formed on the inner circumferential surface with a female thread which is screwed with the male thread of the anchorage. A slope stabilization step of stabilizing the inclined surface by mounting a first head fixing part including a nut member; A pressure transmission tube mounting step of mounting a pressure transmission tube on an upper portion of the slope stabilizing length-type body on which the first head fixing unit is mounted so that a lower end portion of the pressure transmission tube comes into contact with an upper portion of the nut member; Flower bed composition step of forming a concrete flower bed by placing and curing concrete between the slope and the upper end of the slope-shaped longitudinal body; The second head fixing unit is stabilized by mounting a second head fixing unit at an upper end of the slope-shaped longitudinal body, and the second head fixing unit is mounted while applying pressure to the first head fixing unit through the pressure transmitting tube. Flower bed stabilization step; A vegetation soil filling step of filling vegetation soil in the interior space of the concrete flower bed; Greening method by the flower bed composition of environmentally friendly slope stability, characterized in that comprises a. delete delete A slope stabilizing length body comprising a fixing part inserted into and fixed to an insertion hole of a slope and a head extending from the fixing part to be exposed to the outside of the slope, and a head fixing part mounted to the head of the slope stabilizing length body. In the longitudinal member for slope stabilization, The head is mounted with a first head fixing part mounted on a portion crossing the slope and a second head fixing part mounted on an upper end of the head, respectively. The first head fixing unit includes a chiropractic plate having a through hole through which the slope stabilizing body penetrates in the center, and a wedgecon fastening portion formed at an upper portion of the acupressure plate and through which the slope stabilizing length body penetrates, and a male screw thread on an outer circumferential surface thereof. It is formed, the wedge cone is attached to the wedge cone fastening portion and the wedge cone fixed to the longitudinal body for stabilizing the slope, the wedge cone fixing plate is provided on the upper portion of the wedge cone, the wedge cone fixing plate in contact with the slope stable length body It includes a nut member consisting of a top plate formed with a through-hole and a tubular body formed with a female thread that is screwed with the male screw thread of the anchorage on the inner circumferential surface and extends downward from the edge of the upper plate, A pressure transmitting tube is mounted between the first head fixing unit and the second head fixing unit of the head so that one end of the pressure transmitting tube contacts the upper plate of the nut member and the other end contacts the second head fixing unit. Slope stability length member, characterized in that made to. delete delete delete

Images