KR101546723B1 - Stabilizing structure of slope area and construction method of stabilizing slope area using the same - Google Patents

Abstract

The present invention relates to a stabilization structure and a construction method to stabilize an inclined surface using the same capable of preventing loss of soil from an inclined surface by tightly fixating a non-woven fabric using special fixing members when the inclined surface is constructed to be stabilized. The present invention is environmentally friendly by stabilizing a face of a slope and an inclined surface in a river or a revetment using the inclined surface stabilization technology without concrete or shotcrete; has an excellent effect of preventing a loss of the non-woven fabric and the soil therein more than a method to stabilize the inclined surface using existing fixating pins or anchors; and has a short construction period and low increase in costs as construction is not difficult and operation is efficiently performed by installing and constructing the stabilization structure with a simple method. The inclined surface stabilization structure comprises: a non-woven fabric to cover an inclined surface; stones installed in the non-woven fabric, a metallic net to cover an upper part of the stones; and non-woven fabric fixing members inserted in the non-woven fabric in a landslide direction of the inclined surface to fixate the non-woven fabric.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a slope stabilization structure and a slope stabilization construction method using the slope stabilization structure,

The present invention relates to a slope stabilization structure and a slope stabilization construction method using the slope stabilization structure, and relates to a stabilization technique for preventing loss of slope on slopes such as a mountain slope and a river.

Generally, rivers, shores, cut-offs, coasts, etc. are provided with dikes or dikes to prevent flooding of water or seawater or to maintain waterways. Civil engineering structures are installed on the slopes of banks, dikes, parks, and cut-outs for the stability of slopes. These civil structures are structures to prevent erosion by water flowing in rivers and shores, In recent years, there has been a growing demand for environmentally friendly rivers to provide harmony with natural landscapes and habitats for flora and fauna, thus increasing the number of structures that enable vegetation.

In order to stabilize unstable slopes, a variety of slope reinforcement methods have been implemented. Especially, in the case of a slope of a slope or a slope made of a rock, etc., a concrete retaining wall method and a shotcrete Method and the like are used.

However, in the case of the concrete retaining wall construction method, there is no danger of collapse after construction, but when the water isolated from the inside of the slope erodes the inner wall of the concrete, or when the concrete retaining wall collapses rapidly during the freezing and thawing There is a danger of being exposed to the vegetation because the appearance is not good and is not far from eco-friendly method.

In addition, in the case of shotcrete method, it is easy to construct with the use of a rapid hardening agent, and it is almost impossible to make vegetation on a slope because it is fast. However, it is far from an environmentally friendly method, There is a problem that slope collapse can be caused.

Therefore, in recent years, methods of using blocks or stones have been used to prevent soil loss and to enable vegetation.

The block method is a method of installing a block capable of vegetation on a slope of a river or a revetment, and this method is mainly used by installing a geogrid on the bottom surface of the block and installing a block thereon.

The method of using the stone is usually a method of covering a non-woven fabric on an inclined surface, placing a stone on the non-woven fabric, and then fixing the stone using a net made of a metal material.

This method is problematic in that if the floods occur in rivers or reservoirs, or if a large amount of water is introduced, the nonwoven fabric may be peeled off due to hydraulic pressure, and the slope soil may be lost. In order to solve this problem, there have been used methods for preventing the nonwoven fabric and the inside of the nonwoven fabric by inserting the fixing pin into the nonwoven fabric. (Korean Patent No. 10-0830628, No. 10-1374688, Korean Patent Publication No. 10-2009-0077749, etc.)

However, even if the nonwoven fabric is fixed by using the fixing pin, when the large-scale rainwater such as flood is introduced, the fixing pin is pulled out and the role of the nonwoven fabric can not be fulfilled.

In order to solve such a problem, Korean Patent Registration No. 10-1277551 discloses a technique in which an anchor member is fixed to a metal net and an anchor wire is connected to the anchor member, the anchor wire is bent in a U- So that the anchor member is firmly fixed to the metal net and the anchor panel, thereby preventing the loss of the nonwoven fabric and the gravel.

However, in this technique, the anchor panels must be buried in the sand beforehand, which is not easy and there is a problem that the construction period and the cost are excessively required.

Therefore, there is a great need to develop a technique that can prevent the loss of the nonwoven fabric and the soil within the nonwoven fabric by a simple method for stabilizing the inclined plane.

<Other Prior Art Documents>

1. Korean Patent No. 10-1375232

2. Korean Patent Publication No. 10-2011-0072148

3. Korean Utility Model Registration No. 20-0408273

The present invention has been developed in view of the circumstances of the prior art as described above, and it is an object of the present invention to provide a slope stabilization technique capable of stabilizing a slope by an environmentally friendly method but avoiding loss of the non- And to provide a slope stabilization construction technique capable of maintaining the construction effect for a long time.

In order to achieve the above object,

A nonwoven fabric covering the inclined surface;

A stone installed on the nonwoven fabric;

A metal net covering an upper portion of the stone; And

And a nonwoven fabric fixing member embedded in the nonwoven fabric so as to be embedded in the direction of the slope of the inclined surface to fix the nonwoven fabric,

The nonwoven fabric fixing member

A tapered portion having a tapered shape so that the outer diameter increases from the front end to the rear end, and a tapered portion formed to be inclined rearward from the taper portion A wedge member composed of an opening for insertion of the opening and the pipe member;

A rod member penetrating the penetration hole of the wedge member and threadedly engaged with the female screw, a tip portion having a pointed shape at the tip of the rod member, and a pusher bar having a hinge for driving and rotating at the rear end of the rod member;

A pipe member having a diameter smaller than a diameter of the tapered portion and a contact portion of the wedge member and larger than a diameter of the insertion portion, a plurality of pipe branches formed by a plurality of notches having a predetermined length at one end, / RTI &gt;

Wherein the pipe member surrounds the tacking rod by screwing the tacking rod to the wedge member and is bound between the wedge member and the jogging part of the tackle rod,

A plurality of pipe branches of the pipe member are bent by the openings of the wedge member and are branched by rotating the wedge member by rotating the hinge portion of the hinge rod after the wedge member is put on the gravel by using the hinge rod The slope stabilizing structure is characterized in that the slope is penetrated into the surrounding soil.

According to an embodiment of the present invention, the wedge member is provided in the form of a quadrangular to hexagonal cross-section, and the pipe member is also provided in the form of a quadrangular to hexagonal cross section to match the shape of the wedge member.

Further, in one embodiment of the present invention, an insertion hole for inserting a detachable locking part is provided in the lower part of the locking part of the nonwoven fabric fixing member, and the detachable locking part is inserted into the insertion hole to fix the nonwoven fixing member to the nonwoven fabric .

In order to achieve the above object,

(a) fixing a non-woven fabric by inserting a non-woven fabric fixing member in the direction of the slope of the slope on the non-woven fabric after arranging inclined faces and laying a corroded cloth on the arranged slopes;

(b) laying a stone on the fixed nonwoven fabric; And

(c) covering an upper portion of the laid stone with a metal net;

Wherein the slope stabilization method comprises:

In (a), the nonwoven fabric fixing member is embedded in the nonwoven fabric in the direction of the slope of the inclined surface

A tapered portion having a tapered shape so that the outer diameter increases from the front end to the rear end, and a tapered portion formed to be inclined rearward from the taper portion A wedge member composed of an opening for insertion of the opening and the pipe member;

A rod member penetrating the penetration hole of the wedge member and threadedly engaged with the female screw, a tip portion having a pointed shape at the tip of the rod member, and a pusher bar having a hinge for driving and rotating at the rear end of the rod member;

A pipe member having a diameter smaller than a diameter of the tapered portion and a contact portion of the wedge member and larger than a diameter of the insertion portion, a plurality of pipe branches formed by a plurality of notches having a predetermined length at one end, Wherein the pipe member surrounds the hanger rod by screwing the hanger rod to the wedge member and is coupled between the wedge member and the hanger portion of the hanger rod,

A plurality of pipe branches of the pipe member are bent by the openings of the wedge member and are branched by rotating the wedge member by rotating the hinge portion of the hinge rod after the wedge member is put on the gravel by using the hinge rod Wherein the nonwoven fabric is immersed in the surrounding soil so that the nonwoven fabric immobilizing member is embedded and buried on the nonwoven fabric in the direction of the slope of the slope.

Unlike the concrete method or the shotcrete method, the slope stabilization structure and slope stabilization construction method using the slope stabilization structure according to the present invention are environmentally friendly as compared with the method of stabilizing the inclined surface using the conventional fixing pin or using an anchor, It can be installed and constructed by a simple method. Therefore, there is little difficulty in construction and the work can be efficiently performed, which is advantageous in that the construction period and cost increase is not large .

1 is a view showing an inclined plane stabilizing structure and a partially enlarged view according to an embodiment of the present invention.
2 is a cross-sectional view illustrating an example of a nonwoven fabric fixing member used in a slope stabilizing structure according to the present invention.
3 is an exploded view of the nonwoven fabric fixing member according to FIG.
Fig. 4 is a view showing an example of a notch of a five-member in the nonwoven fabric fixing member according to Fig. 2;
Fig. 5 is a view showing the principle of bending the pipe member in the nonwoven fabric fixing member according to Fig. 2;
6 is a view showing another example of the nonwoven fabric fixing member used in the slope stabilizing structure according to the present invention.
7 is a view illustrating a method of stabilizing an inclined plane according to an embodiment of the present invention.

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

1 is a view showing an inclined plane stabilizing structure and a partially enlarged view according to an embodiment of the present invention.

As shown in Figure 1, the inclined plane stabilization structure according to the present invention

A nonwoven fabric (10) covering the inclined surface (S);

A stone 20 disposed on the nonwoven fabric;

A metal net (30) covering an upper portion of the stone; And

And a nonwoven fabric fixing member (100) embedded in the nonwoven fabric in the direction of the slope of the inclined surface to fix the nonwoven fabric.

In the present invention, the nonwoven fabric fixing member 100 is not embedded in the ground due to the wedge structure, so that the nonwoven fabric 10 is firmly fixed, and the possibility that the soil on the inclined surface is lost is small.

2 is an exploded view of the nonwoven fabric fixing member of FIG. 2, FIG. 4 is a cross-sectional view of the nonwoven fabric fixing member of FIG. 2, Fig. 5 is a view showing the principle of bending the pipe member in the nonwoven fabric fixing member according to Fig. 2; Fig.

2 to 5, the nonwoven fabric fixing member 100 includes a wedge member 110, a hinge rod 120, and a pipe member 130.

The wedge member 110 is for putting the nonwoven fabric fixing member 100 in the ground and has four portions: a tapered portion 111, a penetration hole 112, a spreading portion 113, and an insertion portion 114 . The tapered portion 111 is tapered so that its outer diameter gradually increases from the front end to the rear end so that the tapered portion 111 can be easily embedded in the ground. The tapered portion 11 is formed with a penetration hole having a female screw for penetrating the tacking rod. The opening 113 extending from the tapered portion is formed as an inclined surface that is tilted backward from the tapered portion 111 in the central direction and bends and branches the plurality of pipe branches 131 of the pipe member 130 .

The insertion portion 114 extends from the opening portion 113 and is formed in a cylindrical shape. At this time, the area of the cross section where the tapered section 111 and the opening section 113 are contacted is formed wider than the area of the cross section where the opening section 113 and the insertion section 114 are in contact with each other. A female screw (not shown) is formed on the inner peripheral surface of the penetration hole 112. The female screw is formed to have a size corresponding to the male screw 122 provided on the outer circumferential surface of the rod member 121 of the hinge rod 120. The female screw is preferably formed over the entire length of the penetration hole of the wedge member because the rod member 121 of the swing rod must pass through it, but it may be formed only in a part thereof.

The hinge rod 120 is formed of a circular rod having a smaller cross-sectional area than the insertion portion 114 of the wedge member 110. A part or all of the outer circumferential surface of the rod member 121 of the hinge rod 120 is provided with a male screw 122 which can be engaged with the female screw of the penetration hole 112. The tip end of the rod member 121 is provided with a pointed end portion 123 for facilitating the penetration of the soil. The hinge rod 120 may be provided at the other end with a hinge 124 that can be hammered by the hinge. The hinge portion 124 may be formed of a disk or a rectangular plate having a larger area than the hinge rod 120. When the male thread 122 of the hinge rod 120 is fastened to the female thread of the penetration hole 112 of the wedge member 110, the tip end 123 of the hinge rod 120 comes into direct contact with the gravel. The male screw 122 of the hinge rod 120 moves the wedge member 110 in the backward direction and the wedge member 110 moves in the reverse direction when the hinge member 110 of the hinge rod 120 rotates, And the pipe branch supported by the insertion portion of the wedge member 110 is subjected to the force by the opening portion 113 of the wedge member 110 and branches out in the outward direction and is branched.

The pipe member 130 is formed in a pipe shape having a cross sectional area smaller than that of the tapered portion 111 of the wedge member 110 and the opening portion 113 and larger than that of the insertion portion 113. The inserting portion 114 serves to insert one end of a pipe member to be described later and to support it.

A plurality of pipe branches 131 are provided at one end of the pipe member 130, and a latching part 133 is provided at the other end. The plurality of pipe branches 131 form a plurality of notches 132 at a predetermined length at one end of the pipe member 130 and are formed by cutting a plurality of pipe members 130. At this time, the number of the plurality of notches 132 can be appropriately formed as needed. For example, as shown in Fig. 4A, four notches 132 can be formed. In this case, since one end of the pipe member 130 is cut into four pipes, four pipe branches 131 are formed at one end of the pipe member 130. Alternatively, five notches 132 may be formed as shown in FIG. 4 (b). In this case, since one end of the pipe member 130 is cut into five pipes, five pipe branches 131 are formed at one end of the pipe member 130. One end of the pipe member 130 is cut into six pieces so that six pipe branches 131 are formed at one end of the pipe member 130. In this case, .

In the present invention, the number of the notches 132 is four to six, and the wedge member 110 is formed to have a square to hexagonal cross-sectional shape, and the pipe member 130 also has a shape of the wedge member It is preferable to provide a cross-sectional shape of four to six. However, the present invention is not limited thereto, and may be formed in various polygonal shapes.

One end 131a of each of the plurality of pipe branches 131 may be formed to have a sharp edge to facilitate penetration of the gravel into the pipe member 130 where the plurality of notches 132 are formed. The latching part 133 provided at the other end of the pipe member 130 is for catching the pipe member 130 on the nonwoven fabric 10 and may be integrally or separably provided with the pipe member 130 in a plurality of branches. . In addition, both ends of the latching part 133 are bent downward in the form of hooks to tightly tighten the nonwoven fabric.

The pipe member 130 is fixed integrally with the wedge member 110 by the hinge rod 120. Specifically, after one end of the pipe member 130 having the plurality of pipe branches 131 is inserted into the insertion portion 114 of the wedge member 110, one end provided with the male screw 122 of the swinging rod 120 Passes through the pipe member (130), and rotates the hinge portion (124) of the hinge rod to be fastened to the through hole (112) of the wedge member (110). 2, the wedge member 110, the pipe member 130, and the swinging rod 120 are integrally assembled as shown in FIG. 2, when the hinge portion of the hinge rod is rotated so that the pipe member 130 is tightly coupled The nonwoven fabric fixing member 100 is obtained.

When the nonwoven fabric fixing member 100 is put on the slope of the slope S, the tip portion 123 of the hinge rod is positioned at the foil and then the hinge portion 124 of the hinge rod 120 is hammered. Then, the nonwoven fabric fixing member 100 is stuck to the slope of the inclined surface S. Thereafter, when the hinge portion 124 of the hinge rod 120 is rotated using a drill or the like, When the plow branches 131 are bent and the plow branches 131 are bumped into the soil, the plow rods 120 are pulled out to the outside when the plow rods 120 of the plow rods 120 are rotated in opposite directions using drills or the like, The tips 131a of the plurality of pipe branches 131 of the pipe member 130 contacting the openings 113 of the wedge member 110 are bent along the openings 113 The wedge member 110 spreads widely while penetrating into the soil of the side where the wedge member 110 is embedded. The plurality of pipe branches 131 thus diffused enlarge the area of the resistive soil, The plurality of bent pipe branches 131 are rolled back The force required to pull the pipe member 130 reinforces the resistance force of the nonwoven fabric fixing member 10. [

In order to adjust the pull-out resistance of the nonwoven fabric fixing member 100 according to an embodiment of the present invention, the depth of the pipe member 130 to the gravel and the thickness of the pipe member 130 may be adjusted.

6 is a view showing another example of the nonwoven fabric fixing member used in the slope stabilizing structure according to the present invention.

As shown in FIG. 6, an insertion hole for inserting a detachable latch is provided in the lower portion of the latch of the nonwoven fabric fixing member, and a detachable latching portion (fixing pin) is inserted into the insertion hole to fix the nonwoven fixing member to the non- . The nonwoven fabric fixing member is inserted into the insertion hole 133b of the pipe member 130 when the nonwoven fabric fixing member is rotated by rotating the hovering rod and then the pipe member 130 is driven, So that the engaging portion 133a can be hooked on the upper surface of the nonwoven fabric 10.

7 is a view illustrating a method of stabilizing an inclined plane according to an embodiment of the present invention.

Referring to FIG. 7, the slope surface fundusing method according to the present invention includes:

(a) fixing a non-woven fabric by inserting a non-woven fabric fixing member in the direction of the slope of the slope on the non-woven fabric after arranging inclined faces and laying a corroded cloth on the arranged slopes;

(b) laying a stone on the fixed nonwoven fabric; And

(c) covering an upper portion of the laid stone with a metal net;

Wherein the slope stabilization method comprises:

In (a), the nonwoven fabric fixing member is embedded in the nonwoven fabric in the direction of the slope of the inclined surface

A tapered portion having a tapered shape so that the outer diameter increases from the front end to the rear end, and a tapered portion formed to be inclined rearward from the taper portion A wedge member composed of an opening for insertion of the opening and the pipe member;

A rod member penetrating the penetration hole of the wedge member and threadedly engaged with the female screw, a tip portion having a pointed shape at the tip of the rod member, and a pusher bar having a hinge for driving and rotating at the rear end of the rod member;

A pipe member having a diameter smaller than a diameter of the tapered portion and a contact portion of the wedge member and larger than a diameter of the insertion portion, a plurality of pipe branches formed by a plurality of notches having a predetermined length at one end, Wherein the pipe member surrounds the hanger rod by screwing the hanger rod to the wedge member and is coupled between the wedge member and the hanger portion of the hanger rod,

A plurality of pipe branches of the pipe member are bent by the openings of the wedge member and are branched by rotating the wedge member by rotating the hinge portion of the hinge rod after the wedge member is put on the gravel by using the hinge rod So that the nonwoven fabric fixing member is embedded and buried on the nonwoven fabric in the direction of the slope of the slope surface.

First, the tip portion 123 of the sticking bar 120 of the nonwoven fabric fixing member 100 is positioned at a position where the nonwoven fabric fixing member 100 of the slope 10 to be supported is to be installed, .

Next, the nonwoven fabric fixing member 100 of the nonwoven fabric fixing member 100 is hammered with a constant force F to put the nonwoven fabric fixing member 100 to a predetermined depth of the ground. More specifically, when the hammers 124 installed on the hammers 120 of the nonwoven fabric fixing member 100 are driven, the sharp tip 123 of the nonwoven fabric fixing member 100 penetrates the hammers of the slope S, .

After fixing the nonwoven fabric fixing member 100 to a predetermined depth, the nonwoven fabric fixing member 100 rotates the rotation bar 120 using a drill or the like. The wedge member 110 fastened to the male thread 122 of the hinge rod 120 is moved backward while the hinge rod 124 of the hinge rod 120 is rotated, The wedge member 110 is bent in the outward direction by the opening portion 113 of the wedge member 110 and is branched. Then, when the hinge rod 120 is rotated in the opposite direction to the opposite direction, the hinge rod 120 can be completely removed from the pipe member 130. The recovered hinge rod 120 can be reused by being coupled to the other wedge member 110 and the pipe member 130.

At this time, since the tip ends 131a of the plurality of pipe branches 131 are formed to be sharp, they can easily penetrate the ground. When the plurality of pipe branches 131 dig into the ground, the area of the ground supporting the pipe member 130 is widened, so that the supporting force of the pipe member 130 is increased.

When the engaging portion of the pipe member 130 of the nonwoven fabric fixing member 100 is the separable engaging portion 133a, the detachable engaging portion is inserted into the insertion hole 133b before the pipe member of the pipe member is rotated by rotating the engaging rod And the separable catch 133a tightly fastens the nonwoven fabric by rotating the engaging rod.

The slope stabilization structure and the slope stabilization construction method using the slope stabilization structure according to the present invention have been described above. As described above, the inclined surface stabilization technique according to the present invention is environmentally-friendly because it can stabilize the slopes and surfaces such as rivers and revetments without using concrete or shotcrete, and it is possible to use an existing fixing pin or an anchor Since the non-woven fabric and its internal soil can be prevented from being leaked as compared with the method of stabilizing the inclined surface and the installation and construction can be performed by a simple method, there is almost no difficulty in construction and the work can be efficiently performed. There is an advantage that the period and cost increase is not large.

S: slope 10: nonwoven fabric
20: stone 30: metal net
100: Nonwoven fabric fixing member
110: wedge member 111: tapered portion
112: through hole 113:
114: insertion portion 120:
121: Rod member 122: Male thread
123: tip portion 130: pipe member
131: pipe branch 133:

Claims (4)

A nonwoven fabric covering the inclined surface;
A stone installed on the nonwoven fabric;
A metal net covering an upper portion of the stone; And
And a nonwoven fabric fixing member embedded in the nonwoven fabric so as to be embedded in the direction of the slope of the inclined surface to fix the nonwoven fabric,
The nonwoven fabric fixing member
A tapered portion having a tapered shape so that the outer diameter increases from the front end to the rear end, and a tapered portion inclined rearwardly from the tapered portion to the center direction And an insertion portion for inserting the pipe member, the pipe portion being formed in a cylindrical shape extending from the opening portion, wherein the opening portion is larger than the area of the cross section where the taper portion and the opening portion are in contact with each other, A wedge member formed so that an area of a cross section where the opening portion and the insertion portion are contacted is small;
A rod member penetrating the penetration hole of the wedge member and having a male screw on an outer circumferential surface thereof and being screwed to the female thread of the wedge member; a tip portion having a pointed shape at the tip end of the rod member; Wherein a wedge member having a smaller cross-sectional area than an insertion portion of the wedge member is formed as a hinge rod formed by bending a pipe branch of the pipe member by rotation and then pulling the pipe member from the pipe member by counter- Rods;
A pipe member having a diameter smaller than a diameter of the tapered portion and a contact portion of the wedge member and larger than a diameter of the insertion portion, a plurality of pipe branches formed by a plurality of notches having a predetermined length at one end, / RTI &gt;
Wherein the pipe member surrounds the tacking rod by screwing the tacking rod to the wedge member and is bound between the wedge member and the jogging part of the tackle rod,
The wedge members are put into the ground by rotating the wedge members of the wedge members by rotating the wedge members of the wedge members by rotating the wedge members of the wedge members by using the wedge members, Wherein a plurality of pipe branches of the pipe member being supported are bent by receiving an external force by the openings of the wedge member and branching outwardly to penetrate into the surrounding gravel.
The method according to claim 1,
Wherein the wedge member is provided in a quadrangular to hexagonal cross-sectional shape, and the pipe member is also provided in a quadrangular to hexagonal cross-sectional shape so as to match the shape of the wedge member.
The method according to claim 1,
Wherein the non-woven fabric fixing member has an insertion hole for inserting a detachable locking part, and the detachable locking part is inserted into the insertion hole to fix the nonwoven fabric fixing member to the nonwoven fabric.
(a) fixing a non-woven fabric by inserting a non-woven fabric fixing member in the direction of the slope of the slope on the non-woven fabric after arranging inclined faces and laying a corroded cloth on the arranged slopes;
(b) laying a stone on the fixed nonwoven fabric; And
(c) covering an upper portion of the laid stone with a metal net;
Wherein the slope stabilization method comprises:
In (a), the nonwoven fabric fixing member is embedded in the nonwoven fabric in the direction of the slope of the slope
A tapered portion having a tapered shape so that the outer diameter increases from the front end to the rear end, and a tapered portion inclined rearwardly from the tapered portion to the center direction And an insertion portion for inserting the pipe member, the pipe portion being formed in a cylindrical shape extending from the opening portion, wherein the opening portion is larger than the area of the cross section where the taper portion and the opening portion are in contact with each other, A wedge member formed so that an area of a cross section where the opening portion and the insertion portion are contacted is small;
A rod member penetrating the penetration hole of the wedge member and having a male screw on an outer circumferential surface thereof and being screwed to the female thread of the wedge member; a tip portion having a pointed shape at the tip end of the rod member; Wherein the wedge member is formed with a circular rod having a smaller cross sectional area than the insertion portion of the wedge member;
A pipe member having a diameter smaller than a diameter of the tapered portion and a contact portion of the wedge member and larger than a diameter of the insertion portion, a plurality of pipe branches formed by a plurality of notches having a predetermined length at one end, / RTI &gt;
Wherein the pipe member surrounds the tacking rod by screwing the tacking rod to the wedge member and is bound between the wedge member and the jogging part of the tackle rod,
The wedge members are put into the ground by rotating the wedge members of the wedge members by rotating the wedge members of the wedge members by rotating the wedge members of the wedge members by using the wedge members, The plurality of pipe branches of the pipe member being supported are bent by receiving an external force by the widening portion of the wedge member and branched outward so as to be infiltrated into the surrounding gravel so that the nonwoven fabric fixing member is moved on the non- And then pulling the tacking rod from the pipe member by rotating the tacking rod in the opposite direction and lifting the tacking rod in a direction opposite to the ground surface.

Images