KR101935546B1 - Site surface pressure reinforced structure and method for constructing using the same - Google Patents

Abstract

The present invention relates to a bedrock adhesion type rockfall prevention net structure and a construction method thereof and, more specifically, to a bedrock adhesion type rockfall prevention net structure and a construction method thereof, which can prevent surface corrosion. The structure comprises: a soil nail (100) with a length of which a portion is inserted into an inclined surface of an object to be reinforced; a plurality of fixing fins (200) fixed to the inclined surface spaced from the soil nail (100); a wire (1) installed between the soil nail (100) and the fixing fins (200) to prevent surface corrosion of the inclined surface of the object to be reinforced; and a wire tightening unit (300) coupled to pass through an upper end of the soil nail (100) and winding the wire (1) by rotation to apply a tensile force.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a rock-

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a rockfall adhesion type rockfall prevention network structure and a construction method thereof, and more particularly, to a rockfall adhesion type rockfall prevention network structure and a construction method thereof that prevent rock erosion.

Soil nailing method is one of the ground reinforcement methods to stabilize by inserting stiffener in the soil. It inserts the reinforcement into the paperboard at a tight interval without prestressing to increase the overall shear strength of the paperboard itself. This method is widely used as slope reinforcement and flexible ground reinforcement method for excavation surfaces.

Soil nailing method is inexpensive to construct and easy to construct and shorten the construction period by using simple perforation and grouting equipment and it is possible to maintain the ground in a natural state and to select the strength and dimensions of the reinforcement according to the shape of the structure, And can reduce noise and vibration damage.

However, conventionally, the ground reinforcement function of the soil nail is relatively easily lost due to an increase in the external force of the slope, natural deformation occurring in the soil, erosion due to surface water and groundwater outflow, and the problem of massive destruction due to local destruction have.

To overcome this, Korean Patent Registration No. 10-1364586 discloses a nail assembly for a grid nailing slope reinforcement method, a reinforcement facility, and a grid nailing slope reinforcement method using the same, and proposes a method of fixing a wire rope by using a clamp However, there is a problem that a complex process is required to fix the wire rope.

Also, as a rockfall preventing network structure, Registration Practical Utility Model No. 20-0291863 discloses a rockfall preventing network structure using a wire rope. However, the wire rope can not be squeezed onto the installation surface, and thus there is a problem that the effect of preventing rock fall is insignificant.

(Patent Document 1) KR10-1364586 B1

(Patent Document 1) KR20-0291863 Y1

SUMMARY OF THE INVENTION It is an object of the present invention to provide a rock obstruction type rockfall preventing network structure for preventing surface erosion which can easily apply a tensile force to a wire to solve the above problems and a method of construction thereof.

SUMMARY OF THE INVENTION The present invention has been made in order to achieve the above-mentioned object of the present invention, and it is an object of the present invention to provide a soilless nail 100 in which a part of its length is fixedly installed on a slope to be reinforced; A plurality of fixing pins 200 spaced apart from the soil nail 100 and fixed to the slopes; At least one wire (1) installed between the soil nail (100) and the plurality of fixing pins (200) to prevent surface erosion of a slope to be reinforced; A wire tightening part 300 penetrating through the upper end of the sheet nail 100 and applying tension by winding the wire 1 through rotation; And an erosion preventive means (400) penetrating the upper end of the soil nail (100) and provided on the slope at a lower side of the wire tightening part (300).

The erosion preventing unit 400 may be a mesh net, and a part of the erosion preventing unit 400 may be coupled to at least one of the fixing pin 200 and the wire 1. [

The sill nail 100 includes an engaging portion 140 having a male screw portion 101 formed on an outer circumferential surface thereof to be coupled to the wire tightening portion 300. The wire tightening portion 300 is formed of a material having high thermal conductivity, Threaded portion 301 corresponding to the male screw portion 101 is formed on the inner circumferential surface of the through hole 302 through which the nail 100 is passed and can be moved in the longitudinal direction of the nail 100 as the nail 100 rotates.

And a reinforcement nut 110 screwed to the coupling part 140 and screwed to the male screw part 101 to reinforce the fixed state of the wire tightening part 300 .

The wire tightening part 300 includes a rotation part 310 formed with a plurality of penetration parts 311 for passing the wire 1 in a radial direction and rotatably installed with respect to the soil nail 100; The wire 1 is pulled by the rotation part 310 so that the wire 1 is hooked so that the wire 1 is pulled in accordance with the rotation of the rotation part 310 with the soil nail 100 as a rotation axis, And a plurality of latching portions 320 for applying a tensile force to the latching portions 320.

And may include at least one reel 230 spaced apart from the soil nail 100 in order to change the installation direction of the wire 1.

The wire 1 may be wound around the plurality of the fixing pins 200, the plurality of reels 230 and the wire tightening part 300, and the wire 1 may be connected.

A plurality of rock-clinging rockfall-preventing network structures are provided, and the plurality of rock-clinging rockfall-preventing network structures can be connected by wires (1).

A method of constructing a rockfall adhesion type rockfall prevention network structure using a rockfall adhesion type rockfall prevention network structure, comprising: a construction step (P1) of constructing a soil nail (100) and at least one fixation pin (200) in a slope direction; An erosion preventing means installing step (P2) of penetrating the erosion preventing means (400) through the upper end of the soil nail (100) and installing the erosion preventing means (400) on the slope; A coupling step (P3) of coupling the wire tightening part (300) to the soil nail (100); A wire installation step (P4) of winding and connecting the wire (1) to the combined wire tightening part (300) and the fixing pin (200); And a tightening step (P5) of rotating the wire tightening part (300) to apply a tensile force to the wire (1) and closely pressing the wire tightening part (300) and the erosion preventing part (400) A method of constructing a rockfall adhesion type rockfall prevention network structure is disclosed.

The construction step P1 may further include one or more reels 230 spaced around the soil nail 100 to change the installation direction of the wire 1.

The rock obstruction type rockfall prevention network structure and method of construction according to the present invention are advantageous in that erosion can be prevented by reinforcing a slope through a simple method as a soil nailing structure reinforcing a slope by a wire.

Particularly, the rock obstruction type rockfall preventing network structure and the construction method thereof according to the present invention can easily apply a tensile force to a wire by applying a tensile force through rotation through a wire tightening portion provided on a nail to a wire reinforcing a slope, There is an advantage that it is easy to install.

In addition, since the slope prevention wire structure according to the present invention and the construction method thereof are simple and convenient to install the slope reinforcement wire, the construction cost and time are saved as compared with other construction methods, and a tensile force is applied due to rotation, There is an advantage that it can be installed irrespective of skill of the constructor.

The rock obstruction type rockfall prevention network structure and the construction method thereof according to the present invention are advantageous in that a large risk can be prevented by relatively simple construction by providing the rockfall prevention structure on an inclined surface having a rock surface with a risk of rockfall.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a plan view showing a rockfall adhesion type rockfall prevention network structure according to the present invention. FIG.
Fig. 2 is a plan view showing a rock-clinging rockfall prevention network structure constituting the unit body of the rock-bottom-type rockfall prevention network structure of Fig. 1;
Fig. 3 is a side view showing the rockfall adhesion type rockfall preventing network structure of Fig. 2;
Fig. 4 is an exploded perspective view showing the structure of the soil nail and the wire tightening part of the rock-clinging rockfall preventing network structure of Fig. 2;
Fig. 5 is a perspective view showing the shape of the soil nail and the wire tightening part of the rock-fall-type rockfall prevention network structure of Fig. 2;
FIG. 6 is a side view showing a wire bonding state of the wire tightening portion of the rock-fellping type rockfall preventing network structure of FIG. 2. FIG.
7A and 7B are cross-sectional views showing an operation state of the wire tightening part of the rocking-close type rockfall preventing network structure of FIG. 2. FIG. 7A is a sectional view showing a state before rotation of the wire tightening part, Sectional view showing the state after rotation.
Fig. 8 is an enlarged view showing a state of the fixing pin in the rockfall-adhesion type rockfall preventing network structure of Fig. 2;
Fig. 9 is an enlarged view showing a state of a reel among the rockfall-adhering rockfall prevention network structure of Fig. 2;
FIG. 10 is a flowchart showing an embodiment of a method of constructing a rockfall-adhering rockfall prevention network structure using rockfall-adhesion type rockfall prevention network structure of FIG. 2. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 2 to 7, the rock obstruction type rockfall preventing network structure according to the present invention includes: a soil nail 100 in which a part of its length is inserted and fixed to a slope to be reinforced; A plurality of fixing pins 200 spaced apart from the soil nail 100 and fixed to the slopes; At least one wire (1) installed between the soil nail (100) and the plurality of fixing pins (200) to prevent surface erosion of a slope to be reinforced; And a wire tightening part 300 coupled to the upper end of the sheet nail 100 and applying a tensile force by winding the wire 1 through rotation.

It is a further object of the present invention to provide a rockfall-adhering type rockfall preventing network structure according to the present invention which is in close contact with a rock or the like of a slope to be reinforced in order to prevent falling of a slope to be reinforced, Of course.

For example, the slope to be reinforced may be an inclined surface with a risk of falling down due to the joints or crushing of the rocks present on the slope. Specifically, the frozen soil in the inclined region melts as the temperature rises, In which there is a risk of collapse or fall.

For example, in the case of road construction, when a cutout is formed by cutting a mountain or the like, the rock is exposed, and there is a problem in that the rocks may fall on the rock due to climate change or the like.

In this case, it is possible to prevent and reduce the risk through the anti-rockfall network structure according to the present invention, and it can be applied to other slopes or collapse risk general slopes.

The soil nail 100 is of a long rod shape and has a structure in which a part of its length is inserted into a slope to be reinforced, and various configurations are possible.

For example, the soil nail 100 may have a long rod shape having a single outer diameter. Alternatively, the portion exposed to the slope may be formed as a thinner portion with a smaller outer diameter.

The sole nail 100 may be formed in such a shape that one end of the soil nail 100 is inserted into a slope so as to be easily inserted into the slope so as to be suitable for the soil nailing method and is formed sufficiently long to resist the tensile force of the slope .

The male nail 100 may have a male screw portion 101 formed on an outer circumferential surface thereof and a male screw portion 101 may be formed so that the male screw nail 100 may be bolted to a later- And can be vertically movable in the longitudinal direction of the soil nail 100.

At this time, it is needless to say that the male nail 100 may be formed only on a part of the outer circumferential surface in the vicinity of the slope, and may be formed on the entire outer circumferential surface.

That is, the soil nail 100 may include a coupling portion 140 having a male screw portion 101 formed on an outer circumferential surface thereof and coupled to the wire tightening portion 300 described later.

The soil nail 100 may include a spacing member 130 that forms a thickness to secure a thickness of the grouting in a portion to be inserted, And can be coupled to the outer circumferential surface.

For example, the spacer 130 may be formed on the inner circumferential surface of the female thread 131 corresponding to the male thread portion 101, and may be bolted to the needle nail 100.

The plurality of fixing pins 200 are arranged to be spaced apart from each other around the sheet nail 100 and are fixedly mounted on a slope, and various configurations are possible.

For example, the plurality of fixing pins 200 may be provided to provide erosion reinforcement on the slopes of the wire 1, and the wire 1 may be provided with tensile force The fixing pin 200 can be supported.

The fixing pin 200 includes a fixing pin part 210 inserted into a slope surface to resist a tensile force from a surface of the fixing pin part 210, a wire connecting part formed at one end of the fixing pin part 210, 220).

The fixing pin 210 may have a bar shape to be inserted into a slope and may have a sharp side opposite to the wire connecting part 220 to facilitate installation.

The fixing pin unit 210 may be inserted and fixed so as to be firmly fixed to the slope, and more preferably, an injection agent such as grouting may be inserted and fixed to correspond to the tensile force of the wire 1.

On the other hand, the fixing pin portion 210 can securely fix the wire 1 while retaining a circular shape against a physical force such as a change in the external environment with a reinforcing bar.

The wire connection part 220 is configured to connect the wire 1 to the fixing pin 200, and various configurations are possible.

The wire connection part 220 may be integrally formed at one end of the fixing pin part 210 or may be connected through welding or the like and may be formed in a circular shape passing through the center so that the wire 1 is directly connected, The wire connection portion 220 and the wire 1 can be connected to each other.

The wire 1 is installed between the soil nail 100 and the plurality of fixing pins 200 in order to prevent surface erosion of a slope to be reinforced.

The wire 1 may be made of a material having corrosion resistance, heat resistance, and wear resistance such as a wire to prevent corrosion or cutting due to changes in the external environment. As a result, a wire or the like may be used.

Specifically, the wire 1 may be a galvanized steel wire so as to have corrosion resistance, heat resistance and abrasion resistance.

The wire tightening part 300 is configured to penetrate through the upper end of the sheet nail 100 and to apply a tensile force by winding the wire 1 through rotation. Various configurations are possible.

The wire tightening part 300 includes a rotation part 310 formed with a plurality of penetration parts 311 for allowing the wire 1 to pass therethrough and rotatable with respect to the soil nail 100, And a plurality of hooking portions 320 for applying a tensile force to the wire 1 in accordance with the rotation of the rotating portion 310 by causing the wire 1 to be hooked.

The wire tightening part 300 includes at least one fixing part 330 having one end fixedly coupled to the rotation part 310 and the other end fixed to the ground to fix the rotation part 310 .

The rotation unit 310 may be coupled to an upper end of the soil nail 100 so as to be rotatable about the soil nail 100.

The rotation part 310 may have an internal space A and a plurality of through parts 311 may be formed on the outer circumferential surface of the rotation part 310 to allow the wire 1 to pass therethrough.

For example, the rotation unit 310 includes a cylindrical cylindrical body 312 having a plurality of through-holes 311 formed on an outer circumferential surface thereof and having an upper portion thereof opened, (Not shown).

The rotation unit 310 may be configured as an upper plate 313, a lower plate 314 and a cylinder 312. The upper plate 313 and the cylinder 312 are integrally formed, The upper plate 313 may be coupled to the lower plate 314 or the cylinder 312 and the lower plate 314 may be integrally formed.

The rotary part 310 may be formed with an internal thread 301 on the inner circumferential surface of at least one of the upper plate 313 and the lower plate 314 to be coupled with the coupling part 140 of the sheet nail 100, And is movable up and down in the lengthwise direction of the soil nail 100 in accordance with the rotation of the rotation unit 310.

As another example, it may be coupled to the coupling portion 140 of the soil nail 100 through a separate coupling member (not shown).

More specifically, the rotation unit 310 may include the upper plate 313, the lower plate 314, and the cylinder 312. At this time, the upper plate 313 may be formed with a coupling portion (Not shown) may be integrally formed or coupled.

When the joint member is formed to be coupled, the joint member 140 is coupled with the male screw portion 101 formed on the outer circumferential surface of the joint portion 140 of the sheet nail 100 at the upper side of the wire tightening portion 300, The wire tightening part 300 can be moved toward the oblique side with respect to the longitudinal direction of the soil nail 100 by pressurization.

When the coupling member is formed integrally with the upper plate 313, the coupling member may be movable in the longitudinal direction of the soil nail 100 according to the rotation of the rotation unit 310.

It is also a matter of course that the above-described coupling member may be integrally formed on the lower plate 314 or may be integrally formed by welding or the like. In this case as well, 100 in the longitudinal direction and rotation about the soil nail 100 can be induced.

It is needless to say that the female thread portion may be formed on the inner circumferential surfaces of both the upper plate 313, the cylinder 312 and the lower plate 314 in the rotation unit 310.

The engaging portion 320 may be formed on the rotating portion 310 to fix the wire 1 by winding the wire 1 a plurality of times or by fixing the wire 1 to the wire 1, And various configurations are possible.

The engaging portion 320 is formed in the inner space A and more preferably the upper plate 313 and the lower plate 314 in the height direction inside the rotation portion 310 so that the wire 1 can be wound. As shown in Fig.

That is, the latching part 320 is inserted into the rotation part 310 at one end in the height direction to the top plate 313 so as not to be loosened according to the height position where the wire 1 wound around the latching part 320 is wound And the other end can be formed in close contact with the lower plate 314.

The fixing portion 330 is configured to fix the rotation portion 310 to prevent the rotation portion 310 from returning to the state before rotation due to the tensile force of the wire 1 wound around the rotation portion, This is possible.

For example, the fixing part 330 may have one end fixedly coupled to the rotation part 310 and the other end fixedly installed on the ground. More preferably, the fixing part 330 may have a bolt- A pin 333 is formed on the outer surface of the lower plate 314 of the rotary part 310 and a pin fixing hole 332 is formed on the other end of the pin 333, Is inserted and fixed on the paper surface, the rotation of the rotation unit 310 can be prevented.

That is, the fixing part 330 may have a configuration in which one end in the radial direction of the rotation part 310 is installed on the lower plate 314 of the rotation part 310 and the other end is provided on the ground.

As another example, the fixing part 330 may be coupled to the upper plate 313 of the rotation part 310. In this case, as well, the bolt fastening hole 331 formed at one end The pin 330 can be bolted to the upper plate 313 and the rotation of the rotation unit 310 can be prevented by inserting and fixing the pin 333 through the pin fixing hole 332 formed at the other end.

The wire tightening part 300 has a female screw part 301 corresponding to the male screw part 101 formed on an inner circumferential surface of a through hole through which the sheet nail 100 passes, As shown in Fig.

The female threaded portion 301 corresponding to the male threaded portion 101 formed on the outer peripheral surface of the sheet nail 100 may be formed in the through hole 302 of the wire tightening portion 300.

The wire tightening part 300 may be bolted to the sheet nail 100 and the wire tightening part 300 may be rotated according to the direction in which the thread is formed, It can move in the longitudinal direction.

The wire tightening part 300 is configured to apply a tensile force to the wire 1 in a primary direction by rotating the wire tightening part 300 and to move the wire 1 up and down in the longitudinal direction of the sheet nail 100, It can be placed by car, and can be placed close to the slope.

The rocking-close-type rockfall preventing network structure according to the present invention is characterized in that the wire tightening part 300 is installed in close contact with the slope on the sheet nail 100 exposed on the ground, And a reinforcement nut 110 screwed to the support frame 101.

The reinforcing nut 110 is screwed to the coupling part 140 and screwed to the male screw part 101 to reinforce the fixed state of the wire tightening part 300 .

The reinforcement nut 110 is configured to prevent any rotation of the wire tightening part 300 and secure stability of the connection. The reinforcing nut 110 is coupled to the tightening nail 100, And can be variously configured to come in close contact with the upper surface.

The protective nail 110 may further include a protection cap 120 coupled to an upper end of the reinforcement nut 110 to protect a part of the soil nail 100 exposed on the slope and the reinforcement nut 110.

The protective cap 120 may have grooves formed therein for inserting a part of the soil nail 100 and may be formed by various methods such as bolting and fitting, Can be combined.

The rockfall-adhering type rockfall preventing network structure may include at least one reel 230 spaced around the soil nail 100 for switching the installation direction of the wire 1.

The reel 230 is fixedly mounted on a slope surface, and is configured to switch the mounting direction of the wire 1, and various configurations are possible.

For example, the reel 230 includes a reel lower portion 232 having a flat cylindrical shape with an open top formed therein, a reel lid portion 233 coupled to an upper end of the reel lower portion 232, A through hole 234 formed so that the wire 1 can pass through the reel 230 and a reel structure 231 for fixing the reel 230 to the ground.

The reel 230 can advance the installation direction naturally by winding the wire in the inner space and advancing at a different angle from the entering direction through the plurality of through holes 234 formed.

The rockfall-preventing rockfall preventing network structure according to the present invention is installed by connecting the wire 1 to the fixing pin 200, the reel 230, and the wire tightening part 300, 1) can be connected and installed.

Hereinafter, a method of installing and connecting the wire 1 and a rock-clinging rockfall prevention network structure using a plurality of rock-on-rockfall-preventing rockfall-preventing network structures will be described with reference to the accompanying drawings.

The rock-bottomed rockfall preventing network structure according to the present invention is a structure for preventing erosion by connecting a wire (1) and applying a tensile force to the wire (1), and the wire (1) can be connected by various methods.

For example, as shown in FIG. 2, one wire 1 may be wound around and connected to a plurality of the fixing pins 200, the plurality of reels 230, and the wire tightening part 300.

That is, one wire 1 is connected to a plurality of fixing pins 200 via a plurality of reels 230 with the fixing pin 200 as a starting point, thereby constituting a square circumference, So that it can be wound around the wire tightening part 300 and connected.

At this time, the wire 1 is inserted into the inner space A of the wire tightening part 300 through the penetrating part 311 formed at the position corresponding to the fixing pin 200, and the wire 1 is inserted into the fastening part 320 The winding then comes out through a penetration 311 formed at a position corresponding to the fixing pin 200.

Subsequently, after the wire 1 is turned by using the reel 230, and the above process is repeated, a rock-bonded rockfall preventing network structure can be completed with one wire 1. [

In this case also, the one wire 1 is wound around the wire tightening part 300 and connected to at least one of the plurality of the fixing pins 200 and the plurality of reels 230, It is of course possible to complete the fall-prevention network structure.

On the other hand, a plurality of the rockfall-adhering type rockfall preventing network structures are combined to complete a rock-clinging rockfall preventing network structure on a slope where surface erosion is likely to occur, as shown in FIG.

A plurality of rock-to-rockfall-preventing rockfall-preventing network structures are used, and the number of rockfall-adhered rockfall-preventing network structures can be changed according to the slope area.

At this time, the connection of the wires 1 can be connected to each other by using the fixing pin 200 or the reel 230 of the rock-bottom-type rockfall prevention network structure, more preferably by connecting the wires between the reels 230, It is possible to easily form a plurality of them.

Meanwhile, in the rockfall adhesion type rockfall prevention network structure according to the present invention, a resistance increase portion (not shown) may be further added to the end of the soil nail 100, that is, the portion located at the lowest layer of the ground of the perforation hole.

The resistance increasing portion may be integrally formed at the end of the soil nail 100, or may be positioned through a coupling. In this case, a method of welding or the like may be used.

On the other hand, a male screw part may be formed on the outer peripheral surface of the end of the sheet nail 100, and a female screw part may be formed on the resistance increasing part to be coupled by bolt connection.

The resistance increasing portion may include a main body portion to which the end of the soil nail 100 is inserted and coupled and a friction portion that is formed in the main body portion so as to extend in the radial direction of the soil nail 100 to increase friction have.

The main body may be formed with a coupling hole so that a part of an end of the soil nail 100 can be inserted and coupled.

The friction portion may be formed in the body portion to extend in the radial direction of the soil nail 100 and may be formed to resist a tensile force transmitted from the slope.

For example, the friction portion may have a wedge shape as a whole, and may have a shape such that the radius decreases toward the end of the soil nail 100 in order to be inserted without interference when the soil nail 100 is inserted.

If the tensile force is increased from the slope, it can be counteracted by friction with the grout of the friction portion.

Hereinafter, another embodiment for preventing slope erosion of a rockfall-adhesion type rockfall preventing network structure according to the present invention will be described below.

The rock obstruction type rockfall preventing network structure according to the present invention comprises: a soil nail 100 to which a part of its length is fixedly installed on a slope to be reinforced; A plurality of fixing pins 200 spaced apart from the soil nail 100 and fixed to the slopes; At least one wire (1) installed between the soil nail (100) and the plurality of fixing pins (200) to prevent surface erosion of a slope to be reinforced; A wire tightening part 300 penetrating through the upper end of the sheet nail 100 and applying a tensile force by winding the wire 1 through rotation; And an erosion preventing unit 400 penetrating the upper end of the soil nail 100 and installed on the slope at a lower side of the wire tightening unit 300.

The soil nail (100). The detailed description of the plurality of fixing pins 200, the wire 1, and the wire tightening portion 300 will be omitted, as described above.

The erosion preventing unit 400 may be a mesh net, and a part of the erosion preventing unit 400 may be coupled to at least one of the fixing pin 200 and the wire 1. [

The erosion preventing means 400 may be provided on a slope from the lower side of the wire throttle unit 300 and may have various constructions capable of preventing erosion of the slope.

For example, the erosion preventing means 400 may be a mesh network, or more specifically, a geogrid that is made of a lattice structure.

The erosion preventing means 400 may be formed of a material having abrasion resistance, corrosion resistance and the like, provided that the erosion preventing means 400 is provided on a slope for the purpose of reinforcing slopes and is exposed to an external environment.

The erosion preventing means 400 may be attached to the slope surface and may be attached to the slope surface in accordance with the slope contact of the wire throttle portion 300 as described above.

The erosion preventing means 400 may be partly coupled to at least one of the fixing pin 200 and the wire 1. More specifically, the plurality of fixing pins 200 located at the outermost periphery of the slope The outermost portion of the erosion preventing means 400 may be connected to the apparatus.

As another example, the erosion preventing means 400 may be connected to the wire under the wire 1, in which case the wire 1 is entangled with the erosion preventing means 400 Can be connected.

That is, the wire 1 may be alternately intertwined from the lower side to the upper side of the erosion preventing means 400 from the upper side to the lower side.

Hereinafter, a construction method using a rock-bottomed rockfall preventing network structure according to the present invention will be described with reference to the accompanying drawings.

A method of constructing a rockfall-adhesion type rockfall preventing network structure according to the present invention is a method of constructing rockfall-adhesion type rockfall prevention network structure using rockfall adhesion type rockfall prevention network structure, comprising: applying a soil nail (100) (S1); (S2) coupling the wire tightening part (300) to the soil nail (100); A wire installation step (S3) of winding and connecting the wire (1) to the combined wire tightening part (300) and the fixing pin (200); And a tightening step (S4) of rotating the wire tightening part (300) to apply a tensile force to the wire (1) and tightly pressing the wire tightening part (300) against the paper surface.

The construction step S1 is a step of constructing the soil nail 100 and the one or more fixing pins 200 by arranging the slopes flat and forming perforations on the slopes, Into the perforations.

In addition, the construction step S1 may include grouting to inject the injection material into the pierced hole in which the soil nail 100 is inserted, and pouring the shotcrete.

Similarly, the fixing pin 200 may be installed on the slope of the soil nail 100 at a predetermined distance.

The construction step S1 may further include one or more reels 230 spaced around the soil nail 100 to change the installation direction of the wire 1.

The joining step S2 is a step of joining the wire tightening part 300 to the soil nail 100. The joining step S2 is a step of joining the wire tightening part 300 to the portion of the soil nail 100 exposed on the slope, Bond or the like.

The wire installation step S3 is a step of connecting the wire 1 to the wire tightening part 300, the fixing pin 200 and the reel 230 as described above, ) Can be installed on the slope.

In the adhesion step S4, the wire tightening unit 300 is rotated about the sheet nail 100 to apply a tensile force to the wire 1, and the wire tightening unit 300 is tightly pressed against the slope .

Since the wire 1 is hooked on the latching part 320 by rotating the wire tightening part 300, a tension can be applied to the wire 1, The wire tightening part 300 can be moved toward the oblique side of the lengthwise direction of the soil nail 100 as the wire tightening part 300 is rotated along the direction of the screw part 101. [

As a result, a tensile force is further added to the wire 1, and the wire tightening portion 300 can be positioned in close contact with the slope.

After the tightening step S4, at least one fixing part 330, one end of which is fixedly coupled to the wire tightening part 300 and the other end of which is fixed to the ground surface, is provided to fix the wire tightening part 300 And fixing step S5.

The fixing step S5 is a step for preventing the rotation of the rotation unit 310 due to the tensile force of the wire 1 and the one end of the fixing unit 330 is bolted to the lower end of the wire tightening unit 300 And the other end is fixed to the paper surface, the rotation of the rotation part 310 can be prevented.

Meanwhile, another embodiment of a method of constructing a rockfall adhesion type rockfall preventing network structure using rockfall adhesion type rockfall prevention network structure according to the present invention will be described below.

The method of constructing the rockfall-adhesion type rockfall preventing network structure using the rockfall-close-up type rockfall preventing network structure according to the present invention includes a construction step of constructing the soil nail 100 and one or more fixing pins 200 in a slope direction P1); An erosion preventing means installing step (P2) of penetrating the erosion preventing means (400) through the upper end of the soil nail (100) and installing the erosion preventing means (400) on the slope; A coupling step (P3) of coupling the wire tightening part (300) to the soil nail (100); A wire installation step (P4) of winding and connecting the wire (1) to the combined wire tightening part (300) and the fixing pin (200); And a tightening step (P5) of rotating the wire tightening part (300) to apply a tensile force to the wire (1) and closely pressing the wire tightening part (300) and the erosion preventing part .

At this time, the construction step P1 may further include one or more reels 230 installed to be spaced apart from the soil nail 100 in order to change the installation direction of the wire 1.

After the tightening step P5, one or more fixing parts 330 are fixedly coupled to the wire tightening part 300 and the other end is fixed to the ground. (P6).

The construction step P1, the coupling step P3, the wire installation step P4, the adhesion step P5, and the fixing step P6 will not be described in detail as described above.

The erosion preventing means installing step P2 is a step of penetrating the erosion preventing means 400 through the upper end of the soil nail 100 and installing the erosion preventing means 400 on the slope surface.

The erosion preventive means installing step P2 may be provided on the entire reinforcing slope with the soil nail 100 as a center, or may be provided by connecting the unit bodies together, and the whole erosion preventing means may be provided.

The erosion preventive means installing step P2 may be provided on the slope of the erosion preventing means 400 and may be fixed through the center of the sheet nail 100. More preferably, And the outer portion can be connected to the fixing pin 200 or the wire 1 and fixed.

At this time, a wire may be used to connect the fixing pin 200 or the wire 1, and it may be connected using other fastening members.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

1: wire 100: sole nail
200: Fixing pin
300: wire tightening part 400: erosion preventing means

Claims (10)

A soil nail 100 to which a part of the length of the reinforcing slope is inserted and fixed;
A plurality of fixing pins 200 spaced apart from the soil nail 100 and fixed to the slopes;
At least one wire (1) installed between the soil nail (100) and the plurality of fixing pins (200) to prevent surface erosion of a slope to be reinforced;
A wire tightening part 300 penetrating through the upper end of the sheet nail 100 and applying tension by winding the wire 1 through rotation;
And an erosion preventive means (400) penetrating the upper end of the soil nail (100) and installed on the slope at a lower side of the wire throttle (300)
The wire tightening part (300)
A rotation part 310 formed with a plurality of penetration parts 311 for allowing the wire 1 to pass therethrough and installed rotatably with respect to the soil nail 100;
The wire 1 is pulled by the rotation part 310 so that the wire 1 is hooked so that the wire 1 is pulled in accordance with the rotation of the rotation part 310 with the soil nail 100 as a rotation axis, And a plurality of hooking portions 320 for applying a tensile force to the hooking portions 320,
The holding portion 320 rotates in accordance with the rotation of the rotating portion 310 in a state where the wire 1 is wound or fixed a plurality of times so as to wind the wire 1 to apply tensile force,
The soil nail 100 includes a coupling part 140 having a male screw part 101 formed on an outer circumferential surface thereof and coupled to the wire tightening part 300,
The rotary part 310 has a female screw part 301 corresponding to the male screw part 101 formed on an inner peripheral surface of a through hole 302 through which the sheet nail 100 passes, The nail 100 is moved to the oblique side in the longitudinal direction of the nail 100 by rotation so that the erosion preventing means 400 is brought into close contact with the slope and the wire 1 is wound around the outer periphery And a tensile force is applied to the wire (1). The method according to claim 1,
The erosion preventing means 400 is a mesh net,
And a part of the wire is coupled to at least one of the fixing pin (200) and the wire (1). delete The method according to claim 1,
And a reinforcement nut 110 screwed to the coupling part 140 and screwed to the male screw part 101 to reinforce the fixed state of the wire tightening part 300 A rockfall-based rockfall prevention network structure. delete The method according to claim 1,
And at least one reel (230) spaced apart from the soil nail (100) so as to switch the installation direction of the wire (1). The method of claim 6,
Wherein the wire (1) is one and the wire (1) is wound around and connected to a plurality of the fixing pins (200), the plurality of reels (230) and the wire tightening part (300) Protection network structure. Claims [1], [2], [4], [6] and [7], wherein a plurality of rockfall-preventing rockfall preventing network structures are provided, and the plurality of rock- Rockfall adhesion type rockfall prevention network structure. A method of constructing a rockfall-contact type rockfall prevention network structure using rockfall-adhesion type rockfall prevention network structure according to any one of claims 1, 2, 4, 6, and 7,
A construction step (P1) of constructing the soil nail (100) and the at least one fixing pin (200) in a slope direction;
An erosion preventing means installing step (P2) of penetrating the erosion preventing means (400) through the upper end of the soil nail (100) and installing the erosion preventing means (400) on the slope;
A coupling step (P3) of coupling the wire tightening part (300) to the soil nail (100);
A wire installation step (P4) of winding and connecting the wire (1) to the combined wire tightening part (300) and the fixing pin (200);
And a tightening step (P5) of rotating the wire tightening part (300) to apply a tensile force to the wire (1) and closely pressing the wire tightening part (300) and the erosion preventing part (400) Wherein said method comprises the steps of: The method of claim 9,
The method of claim 1, wherein the step (P1) further comprises the step of applying one or more reels (230) spaced around the soil nail (100) to change the installation direction of the wire (1) Construction method of anti - rockfall network structure.

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