KR102108411B1 - Soil nail structure for reinforcing slope and method for constructing using the same - Google Patents

Abstract

The present invention relates to a soil nailing structure and a construction method, and more particularly, to a soil nailing structure and a construction method for preventing surface erosion.
The present invention, the nail portion 100 is fixed and installed a part of the length is inserted into the reinforcement slope; A plurality of fixing pins 200 spaced apart from the thumbnail 100 and fixedly installed on a slope; One or more steel wires 1 installed to prevent surface erosion of the slope to be reinforced between the thumbnail 100 and the plurality of fixing pins 200; Disclosed is a surface erosion-prevention type soil nailing structure, characterized in that it comprises a steel wire tightening part (300) that is penetrated to the upper end of the soil nail (100) and applies tension by winding the steel wire (1) through rotation.

Description

Soil nail structure for reinforcing slope and method for constructing using the same}

The present invention relates to a soil nailing structure and a construction method, and more particularly, to a soil nailing structure and a construction method for preventing surface erosion.

The soil nailing method is one of the ground reinforcement methods that promotes stability by inserting reinforcing materials into the soil, inserting reinforcing materials into the base paper at close intervals without prestressing to increase the overall shear strength of the base itself, and is expected during construction or after construction is over. It refers to a reverse-type cut surface reinforcement method that suppresses ground displacement as much as possible, and is widely used as a method of reinforcing slopes and flexible ground reinforcement methods for excavation surfaces.

The soil nailing method has a low construction cost, and it is easy to construct and shorten the construction period by using simple drilling and grouting equipment. It keeps the ground in a natural state and selects the strength and dimensions of the reinforcement according to the shape of the structure. It has the advantage of being able to reduce the damage of noise and vibration.

However, conventionally, the soil reinforcing function of the soil thumbnail is relatively easily lost due to an increase in the external force on the slope, natural deformation occurring in the soil, and erosion caused by surface water and groundwater leakage, and a large-scale destruction occurs due to local destruction. have.

To overcome this, Korean Patent Registration No. 10-1364586 proposes a nail assembly for a grid nailing slope reinforcement method, a reinforcing facility, and a grid nailing slope reinforcement method using the same. However, this has a problem that requires a complicated process to fix the wire rope.

(Patent Document 1) KR10-1364586 B1

An object of the present invention is to provide a surface erosion prevention soil nailing structure and a construction method that can easily apply a tensile force to one or more steel wires installed to prevent erosion of a slope in order to solve the above problems.

The present invention was created in order to achieve the object of the present invention as described above, the present invention, a portion of the length to be inserted into the reinforcement slope is fixed fixed nail 100 and; A plurality of fixing pins 200 spaced apart from the thumbnail 100 and fixedly installed on a slope; One or more steel wires 1 installed to prevent surface erosion of the slope to be reinforced between the thumbnail 100 and the plurality of fixing pins 200; Disclosed is a surface erosion-prevention type soil nailing structure, characterized in that it comprises a steel wire tightening part (300) that is penetrated to the upper end of the soil nail (100) and applies tension by winding the steel wire (1) through rotation.

The male nail 100, the male screw portion 101 is formed on the outer circumferential surface, the steel wire fastening portion 300, the male screw portion 101 on the inner circumferential surface of the through hole 302 through which the nail nail 100 passes A female screw portion 301 corresponding to is formed, and may move in the longitudinal direction of the thumbnail 100 according to rotation.

A reinforcement nut 110 that is screwed to the male screw portion 101 on the upper surface of the steel wire clamping portion 300 may be included.

The steel wire tightening part 300 includes a plurality of through parts 311 through which the steel wire 1 passes, and a rotatable part 310 rotatable with respect to the thumbnail 100; It is formed on the rotating portion 310, so that the steel wire (1) is caught, it may include a plurality of locking portion 320 for applying a tensile force to the steel wire (1) according to the rotation of the rotating portion (310).

In order to change the installation direction of the steel wire 1, it may include one or more reels 230 spaced apart and installed around the soil nail 100.

The steel wire 1 is one, and the steel wire 1 may be wound around and connected to a plurality of the fixing pins 200, a plurality of the reels 230, and the steel wire fastening portion 300.

Disclosed is a plurality of anti-corrosion type soil nailing structures, and a surface anti-corrosion type soil nailing structure that prevents surface erosion by connecting the plurality of surface anti-corrosion type soil nailing structures with a steel wire (1).

A method for constructing a surface erosion-preventing soil nailing using a surface erosion-preventing soil nailing structure, comprising: a construction step (S1) of constructing a soil nail 100 and one or more fixing pins 200 in a slope direction; A joining step (S2) of joining the steel wire clamping portion 300 to the soil nail 100; A steel wire installation step (S3) of winding and connecting the steel wire 1 to the combined steel wire fastening portion 300 and the fixing pin 200; A surface erosion-prevention type thumbnail comprising rotating the steel wire fastening part 300, applying a tensile force to the steel wire 1, and pressing the steel wire fastening part 300 in close contact with a slope (S4). Disclosed is a ring construction method.

The construction step (S1), in order to switch the installation direction of the steel wire (1), may be additionally installed one or more reels 230 spaced apart and installed around the thumbnail (100).

The surface erosion prevention type soil nailing structure according to the present invention is a soil nailing structure for reinforcing a slope by a steel wire, and has an advantage of preventing erosion by reinforcing the slope through a simple method.

In particular, the surface erosion-prevention type soil nailing structure according to the present invention can easily apply tensile force to a steel wire by applying a tensile force through rotation through one or more steel wire fasteners installed on a nail to a steel wire that reinforces a slope, the There is an advantage of easy installation.

In addition, the construction method of the surface erosion prevention type soil nailing structure according to the present invention is simple and convenient to install steel wires for reinforcing slopes, saving construction cost and time compared to other construction methods, and applying a tensile force according to rotation. Therefore, there is an advantage that can be installed regardless of the skill level of the contractor.

1 is a plan view showing a surface erosion-preventing soiling nailing structure according to the present invention.
FIG. 2 is a plan view showing a soil nailing structure constituting a unit body in the surface erosion preventing soil nailing structure of FIG. 1.
3 is a side view showing the thumbnail structure of FIG. 2.
FIG. 4 is an exploded perspective view showing the configuration of the soil nail and the steel wire clamping part of the soil nailing structure of FIG. 2.
5 is a perspective view showing a state of the thumbnail and the steel wire clamping portion of the thumbnail structure of FIG. 2;
6 is a side view showing a steel wire joining section of the steel wire clamping portion of the nailing structure of FIG. 2.
7A and 7B are cross-sectional views showing the operating state of the steel wire clamping portion of the solenoidal structure of FIG. 2, FIG. 7A is a cross-sectional view showing the state before the steel wire clamping part rotated, and FIG. 7B shows the state after rotation of the steel wire clamping part. It is a cross section showing.
8 is an enlarged view showing a state of the rotating pin among the thumbnail structures of FIG. 2.
9 is an enlarged view showing a state of a reel among the thumbnail structures of FIG. 2.
10 is a flow chart showing an embodiment of the surface erosion prevention type soil nailing construction method using the surface erosion prevention type soil nailing structure of FIG. 2.

Hereinafter, with reference to the accompanying drawings with respect to the surface erosion prevention soil nailing structure and construction method according to the present invention will be described in detail as follows.

The surface erosion-prevention type soil nailing structure according to the present invention includes, as shown in FIGS. 2 to 7, a soil nail 100 in which a part of a length is inserted and fixedly installed on a slope to be reinforced; A plurality of fixing pins 200 spaced apart from the thumbnail 100 and fixedly installed on a slope; One or more steel wires 1 installed to prevent surface erosion of the slope to be reinforced between the nail nail 100 and the plurality of fixing pins 200; It includes a steel wire fastening portion 300 that is penetrated to the upper end of the thumbnail 100, and is wound by winding the steel wire 1 through rotation.

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

For example, the soil nail 100 may be in the form of a long rod having a single outer diameter. Alternatively, the portion exposed to the slope may have a smaller outer diameter and may be formed as a thin portion.

The soil nail 100 may be configured to have a pointed end with one end inserted into the slope to facilitate construction, and may be sufficiently long inserted into the slope to meet the soil nailing method to be sufficiently long to resist the tensile force of the slope. You can.

The male nail 100 may be formed with a male screw portion 101 on an outer circumferential surface, and by being formed with the male screw portion 101, a configuration coupled to the soil nail 100 described later may be bolted. It may be possible to move up and down in the longitudinal direction of the thumbnail (100).

In this case, the thumbnail 100, as well as the male thread portion 101 on the outer circumferential surface can be formed only on a part of the slope, it can be formed on all the outer circumferential surface.

That is, the soil nail 100 may include a coupling part 140 in which a male screw part 101 is formed on an outer circumferential surface and coupled with the steel wire fastening part 300 described later.

The soil nail 100 may include a spacer 130 that forms a thickness in order to secure a grouting thickness in a portion to be inserted, and the spacer 130 is inserted into the soil nail 100 It can be coupled to the outer peripheral surface.

For example, the spacer 130, the female screw 131 corresponding to the male screw portion 101 is formed on the inner circumferential surface may be bolted to the soil nail 100.

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

For example, the plurality of fixing pins 200 may be installed to install the steel wire 1 for erosion reinforcement on a slope, and a tensile force is applied to the steel wire 1 by a steel wire tightening part 300 described later. When applied, the fixing pin 200 may perform a supporting role.

The fixing pin 200 is inserted into the slope, the fixing pin portion 210 for resisting tensile force from the surface, and is formed on one end of the fixing pin portion 210, exposed on the slope, and the steel wire connecting portion to which the steel wire is connected ( 220).

The fixing pin portion 210 may be configured in a rod shape to be inserted into a slope, and the opposite side on which the steel wire connection portion 220 is formed may be sharply formed to facilitate installation.

The fixing pin 210 may be inserted and installed to be firmly fixed to the slope, and more preferably, in order to respond to the tensile force of the steel wire 1, an injection agent such as grouting may be introduced and fixedly installed.

On the other hand, the fixing pin portion 210 can be stably fixed to the steel wire 1 by maintaining a circular shape even with physical forces such as external environmental changes with reinforcing bars.

The steel wire connection part 220 is a configuration for connecting the steel wire 1 to the fixing pin 200, and various configurations are possible.

The steel wire connection part 220 may be integrally formed at one end of the fixing pin part 210, or may be combined through welding, etc., and formed in a circular shape through which the center is directly connected, or the steel wire clip Through the steel wire connection unit 220 and the steel wire (1) can be connected.

The steel wire 1 is a structure that is installed to prevent surface erosion of a slope to be reinforced between the nail thumbnail 100 and the plurality of fixing pins 200, and various configurations are possible.

The steel wire 1 may be formed of a material having corrosion resistance, heat resistance and abrasion resistance, such as iron wire, in order to prevent corrosion or cutting due to changes in the external environment, whereby iron wire or the like can be used.

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

On the other hand, the steel wire 1 is installed to prevent the surface erosion of the slope to be reinforced between the nail nail 100 and the plurality of fixing pins 200, and its material is varied within the scope of achieving its purpose. Of course, it is of course not limited to steel materials.

The steel wire fastening part 300 is a structure that is penetrated and coupled to the upper end of the soil nail 100, and a tension force is applied by winding the steel wire 1 through rotation, and various configurations are possible.

The steel wire fastening part 300, a plurality of through parts 311 are formed so that the steel wire 1 passes, the rotation part 310 rotatable with respect to the thumbnail 100, and the rotation part 310 By making the steel wire 1 to be caught, it may include a plurality of engaging portions 320 that apply a tensile force to the steel wire 1 according to the rotation of the rotating portion 310.

In addition, the steel wire fastening part 300 may include one or more fixing parts 330 having one end fixedly coupled to the rotating part 310 and the other end fixedly installed on the ground to fix the rotating part 310. have.

The rotating part 310 is configured to be rotatable about the thumbnail 100, and may be coupled through the upper end of the thumbnail 100.

In the rotating part 310, an inner space A is formed, and a plurality of through parts 311 may be formed so that the steel wire 1 passes through the outer circumferential surface.

For example, the rotating part 310, a plurality of through parts 311 are formed on the outer circumferential surface and the flat cylindrical cylindrical 312 in which the upper part is opened, and the upper part of the cylindrical 312 covers the inner space (A It may include a top plate 313 to form a.

On the other hand, the rotating part 310, as another example, may be composed of a top plate 313, a bottom plate 314, a cylinder 312, the top plate 313 and the cylinder 312 are integrally formed, the The lower plate 314 may be coupled, or the cylinder 312 and the lower plate 314 may be integrally formed, and the upper plate 313 may be configured to be combined.

The rotating part 310, a female screw portion 301 may be formed on at least one inner circumferential surface of the upper plate 313 and the lower plate 314, through which the coupling portion 140 of the small nail 100 It is possible to move up and down in the longitudinal direction of the thumbnail 100 according to the rotation of the rotating unit 310.

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

More specifically, the rotating part 310, may be composed of the upper plate 313, the lower plate 314 and the cylinder 312, wherein, at this time, an upper portion of the upper plate 313 is formed with a female thread on the inner peripheral surface Members (not shown) may be integrally formed or combined.

When the coupling member is formed, it is coupled on the upper side of the male screw portion 101 and the steel wire fastening portion 300 formed on the outer circumferential surface of the coupling portion 140 of the soil nail 100, by screwing the The steel wire fastening part 300 may be moved to the slope side with respect to the longitudinal direction of the soil nail 100 by pressing.

On the other hand, when the coupling member is integrally formed on the upper plate 313, it is of course possible to move in the longitudinal direction of the thumbnail 100 according to the rotation of the rotating part 310.

Of course, the above-described coupling member may be integrally formed on the lower plate 314 or may be installed in accordance with welding or the like, and in this case, the thumbnails 100 of the steel wire fastening part 300 as described above ) It is possible to induce movement about the longitudinal direction and rotation about the thumbnail (100).

It is of course also possible 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 rotating portion 310.

The locking part 320 is formed on the rotating part 310, and is wound by fixing the steel wire 1 multiple times or by fixing the steel wire 1, thereby fixing the steel wire 1 according to the rotation of the rotating part 310. As a configuration to apply a tensile force to, various configurations are possible.

The engaging portion 320 is formed in the inner space (A), more preferably, so that the steel wire 1 can be wound, the upper plate 313 and the lower plate 314 in the height direction inside the rotating portion 310 ) Can be formed in close contact.

That is, in order to prevent the steel wire 1 wound around the locking portion 320 from being loosened according to the height of the wound, the locking portion 320 has one end in the height direction inside the rotating portion 310 to the top plate 313. Close contact, the other end may be formed in close contact with the lower plate (314).

The fixing part 330 is configured to fix the rotating part 310 in order to prevent the rotating part 310 from returning to a state before rotation due to the tensile force of the steel wire 1 wound with rotation, and various configurations. This is possible.

For example, the fixing part 330, one end is fixedly coupled to the rotating part 310, the other end can be fixedly installed on the ground, more preferably, the fixing part 330 is bolted to one end A ball 331 is formed, and may be bolted to the outer surface of the lower plate 314 of the rotating part 310, a pin fastening hole 332 is formed at the other end, and a pin 333 passing through the pin fastening hole 332 is formed. ) Can be prevented from being rotated by inserting and fixing it on the ground.

That is, the fixing part 330 may be configured such that one end is installed on the lower plate 314 of the rotating part 310 in the radial direction of the rotating part 310 and the other end is installed on the ground.

As another example, the fixing part 330, of course, can be coupled to the top plate 313 of the rotating part 310, in this case also through the bolt fastening hole 331 formed at one end as described above. It can be bolted to the top plate 313, by passing through the pin fastening hole 332 formed at the other end to be fixed by inserting the pin 333 on the ground, it is possible to prevent the rotation of the rotating portion 310.

The steel wire tightening part 300 is formed with a female screw part 301 corresponding to the male screw part 101 on an inner circumferential surface of the through hole through which the nail nail 100 passes, and rotates the small nail part 100 according to rotation. It can move in the longitudinal direction.

A female screw portion 301 corresponding to the male screw portion 101 formed on the outer circumferential surface of the soil nail 100 may be formed in the through hole 302 of the steel wire fastening portion 300.

Accordingly, the steel wire fastening part 300 may be bolted to the soil nail 100, and the steel wire fastening part 300 rotates according to a direction in which a thread is formed, so that the longitudinal direction of the soil nail 100 is achieved. Can be moved.

As a result, the steel wire fastening part 300 firstly applies tensile force to the steel wire 1 by rotating, and in addition, moves up and down in the longitudinal direction of the soil nail 100 to secondaryly pull the tensile force to the steel wire 1. It can be applied, and can be placed in close contact with the slope.

Soil nailing structure according to the present invention is installed so that the steel wire fastening portion 300 is in close contact with the slope on the soil nail 100 exposed on the ground, and the male thread portion 101 from the upper surface of the steel wire fastening portion 300 It may include a reinforcing nut 110 that is screwed.

That is, after the steel wire fastening part 300 is screwed to the coupling part 140, it is screwed to the male screw part 101 to include a reinforcing nut 110 that reinforces the fixed state of the steel wire fastening part 300. You can.

The reinforcing nut 110 is configured to prevent any rotation of the steel wire fastening part 300, and to secure the stability of the coupling, is coupled to the soil nail 100, on the upper surface of the steel wire fastening part 300 It can be a variety of configurations that are in close contact.

In addition, it is coupled to the upper end of the reinforcing nut 110, may include a portion of the thumbnail 100 exposed on a slope and a protective cap 120 for protecting the reinforcing nut 110.

The protective cap 120 has a groove formed therein so that a portion of the nail thumbnail 100 is inserted, and ends exposed on the slopes of the nail nail 100 by various methods such as bolt coupling and fitting coupling. Can be combined.

The soil nailing structure may include one or more reels 230 spaced apart from the soil nail 100 in order to change the installation direction of the steel wire 1.

The reel 230 is fixedly installed on a slope, and is configured to switch the installation direction of the steel wire 1, and various configurations are possible.

For example, the reel 230 includes a flat cylindrical reel lower portion 232 having an internal space and an open top, a reel cover portion 233 coupled to the upper portion of the reel lower portion 232, and the The steel wire 1 may include a through hole 234 formed to pass through the reel 230 and a reel structure 231 for fixing the reel 230 to the ground.

The reel 230, by winding a steel wire in the interior space, through a through-hole 234 formed in a plurality, enters at a different angle from the entry direction, it is possible to naturally switch the installation direction.

On the other hand, the surface erosion-prevention type soil nailing structure according to the present invention is installed by winding the steel wire 1 around a fixing pin 200, a reel 230, and a steel wire fastening part 300 to be installed. The steel wire 1 can be connected and installed.

Hereinafter, a method of installing and connecting the steel wire 1 and a surface erosion-prevention type soil nailing structure installed by using a plurality of soil nailing structures will be described with reference to the accompanying drawings.

The surface erosion-prevention type soil nailing structure according to the present invention connects the steel wire 1 and applies a tensile force to the steel wire 1 to prevent erosion, and the steel wire 1 can be connected according to various methods.

For example, as illustrated in FIG. 2, one steel wire 1 may be connected to a plurality of the fixing pins 200, a plurality of the reels 230, and the steel wire fastening portion 300.

That is, by using one steel wire 1 as a starting point of the fixing pin 200, and connecting to the plurality of fixing pins 200 through a plurality of reels 230, respectively, to form a square circumference, and then reel 230 ), It can be connected to the steel wire fastener (300).

At this time, passing through the through portion 311 formed at a position corresponding to the fixing pin 200, the steel wire 1 is introduced into the inner space A of the steel wire fastening portion 300, and the winding portion 320 is wound around Next, it emerges through the through portion 311 formed at a position corresponding to the fixing pin 200.

Subsequently, after changing the direction of the steel wire 1 using the reel 230, and repeating the above process, it is possible to complete the nailing structure with one steel wire 1.

Even in this case, one of the steel wires 1 is wound around and connected to the steel wire fastening portion 300, and is connected to at least one of the plurality of fixing pins 200 and the plurality of reels 230, so that the nailing is performed. It goes without saying that the structure can be completed.

Meanwhile, as shown in FIG. 1 by combining a plurality of completed soil nailing structures, an anti-erosion type soil nailing structure can be completed on a slope where surface erosion is concerned.

By using a plurality of soil nailing structures, the number of soil nailing structures can be varied according to the area of the slope, and the steel wires 1 can be connected between each soil nailing structure.

At this time, the connection of the steel wires 1 may be connected to each other using a fixing pin 200 or a reel 230 of each soil nailing structure, and more preferably, by connecting a steel wire between the reels 230, Multiple can be formed.

On the other hand, in the surface erosion-prevention type soil nailing structure according to the present invention, an end of the soil nail 100, that is, a portion located at the bottom layer of the perforation hole may be additionally combined with a resistance increasing part (not shown). .

The resistance increasing portion may be integrally formed at the end of the thumbnail 100 or may be positioned through a coupling, in which case a method such as welding may be used.

On the other hand, a male screw portion may be formed on the outer circumferential surface of the end of the soil nail 100, and a female screw portion may be formed on the resistance increasing portion to be coupled by bolting.

The resistance increasing portion may include a body portion to which the end of the nail nail 100 is inserted and coupled, and a friction portion to increase friction by being formed in the body portion to extend in the radial direction of the nail nail 100. have.

In the main body portion, a coupling hole may be formed so that a part of the end of the thumbnail 100 is inserted and coupled.

The friction portion, the body portion is formed extending in the radial direction of the thumbnail (100), it may be formed to combat the tensile force transmitted from the slope.

For example, the friction portion may have a wedge shape as a whole, and may have a shape in which a radius becomes smaller as it goes toward the end of the soil nail 100 in order to be inserted without interference when the soil nail 100 is inserted.

When the tensile force increases from the slope, it can be countered by friction with the grout of the friction portion.

Meanwhile, another embodiment for preventing erosion of the slope of the surface erosion-prevention type soil nailing structure according to the present invention will be described below.

The surface compression-type erosion prevention structure according to the present invention includes: a soil nail 100 in which a part of the length is inserted and fixedly installed on a slope to be reinforced; A plurality of fixing pins 200 spaced apart from the thumbnail 100 and fixedly installed on a slope; One or more steel wires 1 installed to prevent surface erosion of the slope to be reinforced between the nail nail 100 and the plurality of fixing pins 200; A steel wire tightening part 300 which is penetrated to the upper end of the nail nail 100 and applies tensile force by winding the steel wire 1 through rotation; It includes a erosion prevention means that is penetrated to the upper end of the thumbnail (100), and installed on the slope at the lower side of the steel wire clamping part (300).

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

The erosion prevention means is a mesh network, and a part of the fixing pin 200 or the steel wire 1 may be coupled to at least one.

The erosion prevention means, as a configuration that is installed on the slope from the lower side of the steel wire fastener 300, may be various configurations that can prevent the erosion of the slope.

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

The erosion prevention means may be configured as a material having a bar, abrasion resistance, corrosion resistance, etc. which is installed on a slope and exposed to an external environment for reinforcement of a slope.

The erosion prevention means may be installed by being compressed on the slope, and may be compressed on the slope according to the close contact with the slope of the steel wire fastener 300 as described above.

The erosion prevention means, a part may be coupled to at least one of the fixing pin 200 or the steel wire 1, more specifically, to prevent the erosion on a plurality of fixing pins 200 located on the outermost side of the slope The outermost part of the means may be connected and installed.

On the other hand, as another example, it is of course that the erosion preventing means may be connected to the steel wire from the lower side of the steel wire 1, in this case, the steel wire 1 may be entangled with the erosion preventing means.

That is, the steel wires 1 may be connected to each other while being entangled alternately from the upper side to the lower side from the lower side to the upper side of the erosion prevention means.

Hereinafter, a soil nailing method using a surface corrosion preventing type soil nailing structure according to the present invention will be described with reference to the accompanying drawings.

Soil nailing construction method according to the present invention, as shown in Figure 10, in the surface erosion prevention type soil nailing construction method using the above-described soil nailing structure, the soil nail 100 and one or more in the oblique direction A construction step of constructing the fixing pin 200 (S1); A joining step (S2) of joining the steel wire clamping part 300 to the soil nail 100; A steel wire installation step (S3) of winding and connecting the steel wire 1 to the combined steel wire fastening portion 300 and the fixing pin 200; It includes a contact step (S4) of rotating the steel wire fastening part 300, applying a tensile force to the steel wire 1, and pressing the steel wire fastening part 300 in close contact with the ground.

The construction step (S1) is a step of constructing the nail thumbnail 100 and one or more fixing pins 200, which flattens the slope, forms a perforation on the slope, and forms the nail thumbnail 100 It may include a process of inserting into the perforation.

In addition to this, the construction step (S1) may include grouting for injecting an injection material into the perforation where the soil nail 100 is inserted, and pouring shotcrete.

Like this, the fixing pin 200 may be installed on a slope spaced apart from the nail thumbnail 100 by a predetermined interval.

The construction step (S1), in order to switch the installation direction of the steel wire (1), may be additionally installed one or more reels 230 spaced apart and installed around the thumbnail (100).

The joining step (S2) is a step of joining the steel wire fastener 300 to the soil nail 100, bolting the steel wire fastener 300 to a portion of the soil nail 100 exposed on a slope, etc. Can be combined through

The steel wire installation step (S3) is a step of connecting the steel wire 1 to the steel wire fastening part 300, the fixing pin 200 and the reel 230 as described above, and installing the steel wire 1 through various methods. Can be installed on a slope.

In the adhesion step (S4), the steel wire clamping part 300 is rotated about the small nail 100 to apply a tensile force to the steel wire 1, and the steel wire clamping part 300 can be pressed against the slope. .

By rotating the steel wire fastening portion 300, the steel wire 1 is hooked to the locking portion 320 so that it can be wound to apply a tensile force to the steel wire 1, and a male screw portion formed on the outer circumferential surface of the soil nail 100 As it is rotated along the direction of (101), the steel wire fastening part 300 may move to the slope side among the longitudinal directions of the thumbnail 100.

Accordingly, the tensile force is further added to the steel wire 1, and the steel wire clamping portion 300 may be positioned in close contact with the slope.

After the close contact step (S4), one end is fixedly coupled to the steel wire fastening part 300, and the other end is fixed to the steel wire fastening part 300 by installing one or more fixing parts 330 fixedly installed on the ground. (S5).

The fixing step (S5) is a step for preventing rotation according to the tensile force of the steel wire (1) of the rotating part 310, the one end of the fixing part 330 is bolted to the lower end of the steel wire tightening part (300), By fixing the other end to the ground, rotation of the rotating part 310 can be prevented.

On the other hand, the surface erosion prevention type soil nailing construction method using the surface compression type erosion prevention structure which is another embodiment of the erosion prevention structure according to the present invention will be described below.

The surface erosion-prevention soil nailing method using the surface compression-type erosion prevention structure according to the present invention includes a construction step (P1) of constructing a soil nail 100 and one or more fixing pins 200 in a slope direction; An erosion prevention means installation step (P2) of passing through the upper portion of the nail thumbnail 100 and installing the erosion prevention means on the slope; A joining step (P3) of joining the steel wire clamping portion 300 to the soil nail 100; A steel wire installation step (P4) of winding and connecting the steel wire 1 to the combined steel wire fastening portion 300 and the fixing pin 200; It may include a contact step (P5) of rotating the steel wire tightening part 300, applying a tensile force to the steel wire 1, and pressing the steel wire tightening part 300 and the erosion prevention means in close contact with the slope.

At this time, the construction step (P1), in order to switch the installation direction of the steel wire (1), may be additionally installed one or more reels 230 spaced apart and installed around the thumbnail (100).

In addition, after the close contact step (P5), one end is fixedly coupled to the steel wire fastener 300 and the other end is fixed to the ground by installing one or more fixing parts 330 to fix the steel wire fastener 300 It may include a fixing step (P6).

The construction step (P1), the coupling step (P3), the steel wire installation step (P4), the adhesion step (P5) and the fixing step (P6) as described above, detailed description thereof will be omitted.

The erosion prevention means installation step (P2) is a step of installing the erosion prevention means on the slope through the top of the nail thumbnail 100, and may be performed by various methods.

The erosion prevention means installation step (P2) may be installed on the entire reinforcing slope around the soil nail 100, and may be installed by connecting units, as well as a single erosion prevention means.

Erosion prevention means installation step (P2), the erosion prevention means can be installed on a slope, and fixed through the center of the thumbnail 100, more preferably, the outermost portion of the erosion prevention means is the fixing pin ( 200) or by connecting with a steel wire (1).

In this case, when connecting with the fixing pin 200 or the steel wire 1, a steel wire can be used, and of course, it can be connected using other fastening members.

The above is merely a description of some of the preferred embodiments that can be implemented by the present invention, so, as is well known, the scope of the present invention should not be construed as being limited to the above embodiments, and the present invention described above. It will be said that all of the technical ideas and the technical ideas that accompany the fundamentals are included in the scope of the present invention.

1: Steel wire 100: Thumbnail
200: fixing pin
300: steel wire fastener

Claims (9)

A small nail 100 in which a part of the length is inserted and fixedly installed on the slope to be reinforced;
A plurality of fixing pins 200 spaced apart from the thumbnail 100 and fixedly installed on a slope;
One or more steel wires 1 installed to prevent surface erosion of the slope to be reinforced between the nail 100 and the plurality of fixing pins 200;
It is coupled to the upper end of the thumbnail (100), and includes a steel wire tightening part (300) to apply tensile force by winding the steel wire (1) through rotation,
The steel wire fastener 300,
A rotating part 310 in which a plurality of through parts 311 are formed so that the steel wire 1 passes in a radial direction, and rotatably installed with respect to the thumbnail 100;
It is provided in the rotating part 310, so that the steel wire (1) is caught, the steel wire (1) by pulling the steel wire (1) in accordance with the rotation of the rotating portion (310) with the thumbnail 100 as a rotation axis ) Includes a plurality of engaging portions 320 for applying tensile force,
The engaging portion 320, the steel wire (1) is wound or fixed a plurality of times, or in a fixed state, rotates according to the rotation of the rotating portion 310, winding the steel wire (1) to apply a tensile force,
The thumbnail 100, the outer peripheral surface of the male screw portion 101 is formed includes a coupling portion 140 coupled to the steel wire fastening portion 300,
In the rotating part 310, a female screw part 301 corresponding to the male screw part 101 is formed on an inner circumferential surface of the through hole 302 through which the nail nail 100 penetrates, so that the small nail 100 is coupled. By bolting with the part 140, the steel wire 1 is moved to the slope side in the longitudinal direction of the nail thumbnail 100 through rotation, and the steel wire 1 is closely adhered to the slope, and the steel wire 1 is wound around the outer periphery. (1) A surface erosion-prevention soil nailing structure characterized by applying a tensile force. delete The method according to claim 1,
The steel wire fastening portion 300 is screwed to the coupling portion 140 and screwed to the male screw portion 101, characterized in that it comprises a reinforcing nut 110 to reinforce the fixed state of the steel wire fastening portion 300 Soil nailing structure to prevent surface erosion. delete The method according to claim 1,
The surface erosion-prevention type soil nailing structure characterized by including one or more reels 230 spaced apart from the soil nail 100 and installed on a slope, and the steel wire 1 is wound to change the installation direction. . The method according to claim 5,
A surface erosion-prevention type small nailing structure characterized in that one steel wire (1) is wound around and connected to a plurality of the fixing pins (200), a plurality of the reels (230), and the steel wire fastening portions (300). Claim 1, claim 3, claim 5 and claim 6 according to any one of the surface anti-corrosion type soil nailing structure is plural, and the surface of the plurality of surface anti-corrosion type soil nailing structure connected by a steel wire (1) Soil nailing structure to prevent erosion by preventing erosion. In claim 1, claim 3, claim 5 and claim 6, wherein the surface erosion prevention type soil nailing construction method using the surface erosion prevention type soil nailing structure according to any one of the claims,
A construction step (S1) of constructing the soil nail 100 and one or more fixing pins 200 in a slope direction;
A joining step (S2) of joining the steel wire clamping portion 300 to the soil nail 100;
A steel wire installation step (S3) of winding and connecting the steel wire 1 to the combined steel wire fastening portion 300 and the fixing pin 200;
A surface erosion-prevention type thumbnail comprising rotating the steel wire fastening part 300, applying a tensile force to the steel wire 1, and pressing the steel wire fastening part 300 in close contact with a slope (S4). Ring construction method. The method according to claim 8,
The construction step (S1), the surface erosion, characterized in that to install one or more reels (230) spaced apart from the center of the small nail (100) for the installation direction change of the steel wire (1) additionally installed Preventive Soil Nailing Construction Method.

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