KR20190100753A - Ground reinforcing method using compressive ground pressure type ground anchor - Google Patents

Abstract

The present invention relates to a ground reinforcement method using a compressive permanent ground anchor, capable of preventing the collapse of soil. The ground reinforcement method includes: a punching hole formation step (S1) of forming a punching hole by punching reinforcement target around; an insertion step (S2) of inserting a hollow pipe (200) into the punching hole formed through the punching hole formation step (S1); an injection step (S3) of injecting a grout material through a grout hose (120) of an inserted tension application part (100); and a combination step (S4) of curing the injected grout material, and combining a head part (300) with the other end of the tension application part (100).

Description

Ground reinforcing method using compressive ground pressure type ground anchor}

The present invention relates to a ground reinforcement method, and more particularly, to a ground reinforcement method using a pressure compression type permanent ground anchor used for various purposes such as reinforcement of soil, reinforcement of various structures, prevention and stabilization of slope.

As the industry develops, it is inevitable to develop steep slopes such as mountain areas by complex construction, construction of new towns, and road construction. Therefore, it is possible to improve land use, secure stability and comfort of residential complex, The establishment of slope stabilization method that can satisfy the integrity is required.

Ground anchoring method is a type of slope stabilization method. It is a method that is used for earthquake by pressing slope with fear of collapse or using with retaining wall, etc., inserting steel bar or PC steel bar into boring hole drilled in rock, After filling by filling with mortar or resin into the rock part, the anchor head is fixed with metal parts to strengthen the entire soft rock or loose rock.

On the other hand, in the case of the conventional anchor, in order to increase the frictional force with the ground, the length is formed long and installed deep in the ground, which causes a rise in unit cost and construction difficulties, there is a problem that the cost and construction time increases.

In this regard, Korean Patent No. 10-1158512 discloses a compression type permanent anchor and a construction method thereof, which are relatively short in length but can perform the reinforcement function of the ground appropriately and obtain economic effects, but have frictional force with the ground. There is a problem that it is not enough to stick to the slope stability of the permanent anchor.

(Patent Document 1) KR10-1158512 B1

An object of the present invention, in order to solve the problems as described above, in order to prevent the collapse of the laminated soil, the anchoring pressure-type permanent ground anchor that can greatly improve the anchor force by using the frictional force and the ground pressure of the ground It is to provide a ground reinforcement method using.

The present invention was created in order to achieve the object of the present invention as described above, the present invention, a pressure-pressure-type permanent ground anchor is installed through the soil is formed on one side, a plurality of wires 110, A tensioning unit (100) consisting of one or more grout hoses (120) for performing grouting; A part of the tensioning part 100 is inserted from one end of the tensioning part 100 and is embedded in the soil to increase the resistance to tensile force to the outside when the tension is applied to the tensioning part 100. Hollow pipe 200 and; In the ground reinforcement method using the pressure-compression type permanent ground anchor is coupled to the other end of the tension action part 100, the head portion 300 is exposed to the other side of the earth and sand,

A drilling hole forming step (S1) of forming a drilling hole by drilling the ground to be reinforced;

An insertion step (S2) of inserting the tension action part (100) and the hollow pipe (200) into the drilling hole formed through the drilling hole forming step (S1);

 An injection step (S3) of injecting grout material through the grout hose 120 of the tension action part 100;

Curing the injected grout material, and includes a coupling step (S4) for coupling the head portion 300 to the other end of the tension action portion 100,

Before the insertion step (S2), the length of the hollow pipe 200 has a plurality of resistance increasing portion 400 to further increase the resistance to the tensile force to the outside when the tension is applied to the action portion 100 Disclosed is a ground reinforcement method using a pressure compression type permanent ground anchor, characterized in that arranged sequentially along the direction to the outside of the hollow pipe (200).

The hollow so that the outer diameter from the center of the hollow pipe 200 increases the plurality of resistance increasing parts 400 from one end to the other from the other end of the tension action part 200 along the longitudinal direction of the hollow pipe 200. It may be coupled to the outside of the pipe 200.

The plurality of resistance increasing units 400 may have a ring shape fitted into an outer circumferential surface of the hollow pipe 200.

The plurality of resistance increasing units 400 may have a ring shape integrally formed, or a plurality of members may be combined to form the ring shape.

The hollow pipe 200 may form a protrusion 230 on the outer circumferential surface to further increase the resistance to the tensile force to the outside when the tension is applied to the tension action part 100.

The protruding portion 230 is a male screw portion 231 formed on the outer circumferential surface of the hollow pipe 200 and having a spiral structure, and the resistance increasing portion 400 is screwed to the male screw portion 231 on the inner circumferential surface. The female screw part 430 may be formed to include a nut member screwed to the hollow pipe 200.

The protrusion 230 has an annular ring shape on the outer circumferential surface of the hollow pipe 200, and the resistance increasing part 400 inserts the protrusion 230 into the inner circumferential surface thereof, and the recesses 441 and 451. It may include one or more clamp members (440, 450) formed.

The plurality of resistance increasing parts 400 may increase in diameter from the other end of the tension action part 200 along the longitudinal direction of the hollow pipe 200 to the outer diameter from the center of the hollow pipe 200. have.

The hollow pipe 200 includes a fixing member 410 for supporting the resistance increase unit 400 in order to prevent the resistance increase unit 400 from being pushed outward in a state in which the plurality of resistance increase units 400 are coupled to the hollow pipe 200. It can be installed on the outer circumferential surface of the).

The head portion 300 is coupled to the tension action portion 100, is installed through the earth and sand, the manshon 310 and the manseon 310 to form a male thread portion 311 on the outer circumferential surface And acupressure plate 320 in close contact with the earth and sand; The mansion 310 may include a reinforcing nut 330 coupled to the pressure plate 320 in close contact with the upper surface side of the pressure plate 320.

The head part 300 may be coupled to the end of the manshon 310, and may combine a portion of the manshon 310 with a protective cap 340 protecting the reinforcing nut 330.

The front end head 210 to which one end of the plurality of wires 110 of the tensioning unit 100 is coupled may be coupled to the first end of the hollow pipe 200 in the longitudinal direction of the hollow pipe 200. have.

The tip cap 220 may be covered by a tip cap 220 where the one end of the tensioning unit 200 of the tip head 210 of the tip head 210 is coupled.

The ground reinforcement method using the acupressure compression type permanent ground anchor according to the present invention has an advantage of stably supporting a structure installed in soil by increasing frictional force with the ground according to the installation of the resistance increasing member.

In particular, the ground reinforcement method using the acupressure compression type permanent ground anchor according to the present invention can maximize the frictional force with the ground through the combination of the resistance increasing member, which is a relatively simple method, through which the constant, regardless of the skill of the contractor There are advantages such as construction condition, construction time shortening and construction cost reduction.

In addition, the ground reinforcement method using the acupressure compression type permanent ground anchor according to the present invention is a construction method of maximizing the anchor force with the ground through the coupling of the resistance increase, it is excellent in the field assembly, combined with the resistance increase regardless of place It can be through a simple site construction, there is an advantage that easy to carry and manufacture.

In addition, the ground reinforcement method using the acupressure compression type permanent ground anchor according to the present invention can be combined with the resistance increasing member in a simple and various ways, according to the construction environment and drilling holes of the appropriate resistance increase member Since it can be combined, there is an advantage that can obtain the optimum construction effect according to the working environment.

On the other hand, the ground reinforcement method using the pressure-pressure permanent ground anchor according to the present invention is a construction method using a pressure-pressure permanent ground anchor with increased frictional resistance with the ground bar, its construction is simple and less influence on the construction ability of the builder It has the advantage of low cost of construction.

1 is a view showing a state in which the rod-shaped acupressure compression type permanent ground anchor according to the first embodiment of the present invention is installed.
FIG. 2 is a view showing a resistance increase member coupled to a hollow pipe among the bar-type acupressure compression permanent ground anchor of FIG. 1.
3A and 3B are cross-sectional views showing cross-sections of the bar-shaped pressure-bearing permanent ground anchors of FIG. 2, and FIG. 3A is a cross-sectional view seen from the AA direction in FIG. 2, and FIG. 3B is a cross-sectional view seen from the CC direction in FIG. 2. .
FIG. 4A is a partial side view showing a state of the resistance increasing member installed in the bar-type pressure-bearing permanent ground anchor of FIG. 1, and FIG. 4B is a longitudinal cross-sectional view of the X direction in FIG. 4A.
FIG. 5 is a sectional view seen from the BB direction in FIG. 2. FIG.
FIG. 6 is a longitudinal sectional view showing the head of the steel bar type pressure compression permanent ground anchor of FIG. 1. FIG.
FIG. 7 is a longitudinal cross-sectional view showing a coupling relationship between a tip head and a tip cap of the rod-shaped acupressure compression permanent ground anchor of FIG. 1.
FIG. 8 is a plan view showing a leading head of the rod-shaped acupressure compression permanent ground anchor of FIG.
FIG. 9 is a view showing a nut-type acupressure type permanent ground anchor installed according to a second embodiment of the present invention.
FIG. 10 is a view illustrating a resistance increase member coupled to a hollow pipe among the nut-type acupressure-type permanent ground anchors of FIG. 9.
11A and 11B are cross-sectional views showing the nut-shaped acupressure compression type permanent ground anchor of FIG. 10, and FIG. 11A is a cross-sectional view taken from the direction AA in FIG. 10, and FIG. 11B is a cross-sectional view viewed from the direction CC in FIG. 10. to be.
FIG. 12A is a partial side view showing a state of the resistance increasing member installed in the nut-type acupressure compression permanent ground anchor of FIG. 9, and FIG. 12B is a longitudinal cross-sectional view in the X direction in FIG. 12A.
FIG. 13 is a cross-sectional view seen from the BB direction in FIG. 10.
FIG. 14 is a longitudinal cross-sectional view showing a head portion of the nut-type shiatsu compression permanent ground anchor of FIG. 9.
FIG. 15 is a longitudinal cross-sectional view showing a coupling relationship between a tip head and a tip cap of the nut-type acupressure compression permanent ground anchor of FIG. 9.
FIG. 16 is a plan view showing a leading head of the nut-type shiatsu compression permanent ground anchor of FIG. 9.
17A and 17B are side and longitudinal cross-sectional views showing the configuration of a modified hollow pipe and a resistance increasing member coupled thereto, respectively.
Figure 18 is a flow chart showing a method of ground reinforcement using acupressure compression permanent ground anchor according to the present invention.

Hereinafter, the pressure-bearing permanent ground anchor according to the present invention and the ground reinforcement method using the same will be described in detail with reference to the accompanying drawings.

Acupressure compression type permanent ground anchor and ground reinforcement method using the same according to the present invention, in addition to the hollow pipe for forming the anchor force by the frictional force with the ground, the tension is applied to the tension-actuating portion made of a wire coupled to the hollow pipe By further providing a plurality of resistance increasing portion to further increase the ground pressure of the ground, there is a technical point to greatly improve the anchor force by using the frictional force with the ground and the ground pressure of the ground.

Various embodiments are possible according to the technical gist of the present invention. Hereinafter, the present invention will be described with reference to optimized embodiments.

Steel bar type pressure-pressure permanent ground anchor according to the first embodiment of the present invention, as shown in Figures 1 to 8, in the pressure-pressure permanent ground anchor is installed through the soil having a slope formed on one side, a plurality A tensioning unit 100 consisting of wires 110 and one or more grout hoses 120 for performing grouting; A part of the tensioning unit 100 is inserted from one end of the tensioning unit 100, and is embedded in the soil to increase the resistance to the tensile force to the outside when the tension is applied to the tensioning unit 100 ( 200); The other end of the tension action unit 100 is coupled, and includes a head portion 300 exposed to the other side of the structure (1).

On the other hand, the rod-shaped acupressure compression type permanent ground anchor of the present invention, may be installed through the structure (1) for supporting the soil is formed sloped on one side, the structure (1), the stacked earth or sand As a structure which does not collapse, various structures are possible.

For example, the structure 1 may be installed in various ways according to the environment of the construction site, such as wood, concrete, reinforced concrete as a wall of earth.

Through this, the structure 1 is directly subjected to earth pressure, it can be supported without collapse by the acupressure compression type permanent ground anchor to be described later.

Here, the rod-shaped acupressure compression permanent ground anchor according to the present invention may be installed through the structure (1) for supporting the soil having a slope formed on one side, for example, the position or construction site where the erosion is concerned, such as the slope The structure 1 may be installed in the stacked soil during the digging operation, and may be installed to resist the tensile force transmitted from the soil to the structure 1.

The tension unit 100 is composed of a plurality of wires 110 and one or more grout hoses 120 for performing grouting, and various configurations are possible.

The wire 110 is a member that withstands the tension of the ground anchors, it is composed of a single steel wire, or a plurality of configuration is possible, such as being installed in a twisted state with each other.

And the wire 110, as shown in Figure 3a and 3b, a plurality of wires 110 are twisted to form one cable 130, the cable 130 is a hose made of synthetic resin material Various configurations are possible, such as being fitted in the installation.

On the other hand, the hose, the configuration surrounding the plurality of wires 110, may be a high density polyethylene.

The hose may have a radius such that a plurality of wires 110 are located therein and grease may be sufficiently filled between the plurality of wires 110 and the hose.

Therefore, the hose, the plurality of wires 110 is located inside, the grease may be filled around.

The tension unit 100 is coupled to the circumferential direction so that the plurality of cables 130 and the grout hose 120 made of a plurality of twisted wires 110 are fitted to each other to maintain a constant distance from each other. The groove 141 may include the gap maintaining member 140.

The tension action unit 100, the earth pressure delivered to the structure (1) acts as a tension, it may serve to transfer this tension to the hollow pipe 200, a large tension can be applied according to the earth pressure. It is preferably composed of a steel wire material having excellent durability.

The wire 110 may transmit the tension transmitted from the structure 1 to the hollow pipe 200 and may be supported by the frictional force between the ground and the grout of the hollow pipe 200, thereby preventing soil from being collapsed. .

The grout hose 120 is a configuration for forming a grout therein by injecting grout material into the space between the boring hole and the member where the acupressure compression type permanent ground anchor according to the present invention is installed, and various configurations are possible. .

The grout hose 120 is a configuration in which the grout material injected from the outside is introduced into the drilling hole, and various configurations are possible.

For example, the grout hose 120, PE pipe may be used to sufficiently withstand the pressure of the grout is injected.

The space maintaining member 140, the coupling groove 141 is formed in the circumferential direction so that the cable 130 and the grout hose 120 is fitted, and as a configuration for securing the internal space, various configurations are possible. .

The gap maintaining member 140, the coupling groove 141 of the circumferentially concave shape is formed, the grout hose 120 and the cable 130 can be fitted and coupled, through which the grout hose 120 and the cable The 130 may be spaced apart from each other to form a space therebetween.

The space maintaining member 140, one or more may be installed, a plurality of installed along the longitudinal direction between the head portion 300 and the hollow pipe 200 of the drilling hole for installing the acupressure compression type permanent ground anchor desirable.

On the other hand, the wire 110, that is, the cable 130, one end is fixedly coupled to the head portion 300, the other end may be coupled to the front end cap 220 through the hollow of the hollow pipe 200.

In addition, the grout hose 120, in order to form a grout in the hollow of the hollow pipe 200, it may be installed with a length located to the end of the tension-acting portion 100 side of the hollow pipe (200).

The head portion 300, the other end of the tension action unit 100 is coupled, as a configuration exposed to the other side of the structure (1), various configurations are possible.

The head portion 300, the other end of the tension action portion 100 is coupled, and installed to penetrate the structure (1) to be exposed to the outside, the manseon 310, the male thread portion 311 is formed on the outer peripheral surface, Coupled to the manshon 310, the pressure plate 320 is in close contact with the structure (1), and the reinforcing nut 330 is coupled to be in close contact with the pressure plate 320 on the upper surface side of the pressure plate 320 of the manshon 310 Can be.

In addition, the head part 300 may further include a protective cap 340 coupled to the end of the manshon 310 to protect a part of the manshon 310 and the reinforcing nut 330.

The manshon 310, the other end of the tension action unit 100 is coupled, as a configuration to be exposed to the outside through the structure (1), various configurations are possible.

For example, the manshon 310 may include a member 350 for stably coupling the tensioning unit 100.

In this case, the tension action unit 100 may be formed through the manshon 310, and may be coupled to the manshon 310 to stably transfer the tension to the hollow pipe 200.

The coupling member 350 may be coupled to or formed on the tension action part 100 side of the manshon 310, and may compress and fix a portion of the tension action part 100 penetrating the manshon 310. .

The pressure plate 320 is configured to be in close contact with the structure (1), various configurations are possible.

The pressure plate 320 may transmit the frictional force transmitted from the hollow pipe 200 to the structure 1 to prevent the structure 1 from collapsing. In this case, the pressure plate 320 may be applied to the structure 1. It is preferable to be in close contact.

For example, the acupressure plate 320 may be installed at a pressure compression type permanent ground anchor installed at a predetermined angle from the normal of the structure 1, and in this case, the pressure plate 320 may be connected to the structure 1. An adapter 3 may be further formed or coupled to the structure 1 so as to be in close contact.

The reinforcing nut 330 is configured to press the pressure plate 320 to be in close contact with the structure 1, and is screwed to the manshon 310 on the upper surface of the pressure plate 320 to press the pressure plate 320. Can be.

The protective cap 340 is configured to be coupled to the end of the manshon 310 at the top of the reinforcing nut 330, it may be a truncated cone shape.

The protective cap 340 may have a radius to protect the reinforcing nut 330 on the reinforcing nut 330 side, the inner width 341 is coupled to the end of the manshon 310, Manshon 310 It may correspond to the width of.

On the other hand, in this case, it is a matter of course that the female screw portion corresponding to the male screw portion 311 is formed in the protective cap 340 can be screwed.

The hollow pipe 200, a part of the tension action portion 100 is inserted from one end of the tension action portion 100, buried in the earth and to the tension force to the outside when the tension is applied to the tension action portion 100 As a configuration for increasing the resistance to, various configurations are possible.

The hollow pipe 200 has a cylindrical shape in which a hollow is formed so that the plurality of cables 130 can pass therethrough, and is embedded in the hollow pipe for a long time, and is a durable material, and has excellent corrosion resistance and abrasion resistance. Can be used.

The hollow pipe 200 may have a surface structure such that an outer circumferential surface thereof has a plurality of protrusions and predetermined roughness to increase frictional force.

On the other hand, the rod-shaped acupressure compression type permanent ground anchor according to the present invention, as shown in Figure 4, is disposed sequentially along the longitudinal direction of the hollow pipe 200, is coupled to the outside of the hollow pipe 200, tension action When the tension is applied to the portion 100 may further include a plurality of resistance increasing unit 400 for further increasing the resistance to the tensile force to the outside.

The plurality of resistance increasing units 400 are sequentially disposed along the longitudinal direction of the hollow pipe 200 and coupled to the outside of the hollow pipe 200, when the tension is applied to the tensioning unit 100. Various configurations are possible as the configuration to further increase the resistance to the tensile force to.

In particular, the plurality of resistance increase parts 400, as shown in Figure 2, the outer diameter from the center of the hollow pipe 200 from the other end of the tension action portion 200 along the longitudinal direction of the hollow pipe 200 It is desirable to be installed so as to increase to one end.

More specifically, the resistance increasing unit 400, as shown in Figures 2 and 4, may be disposed along the longitudinal direction of the hollow pipe 200, the outer diameter (D _i ) and the spacing (L _i) ) May be arranged in various ways.

The resistance increasing unit 400 may be coupled to the outer circumferential surface of the hollow pipe 200 by various methods.

For example, the resistance increase unit 400, the through-hole having an inner diameter corresponding to the outer diameter of the hollow pipe 200 is formed, can be fitted into the hollow pipe 200 and coupled, more preferably as a clamp By adjusting the radius of the through hole through one end of the bolt, it may be in close contact with the hollow pipe 200.

Hereinafter, an embodiment of maximizing the anchoring force corresponding to the tensile force transmitted from the structure 1 through the method of arranging and coupling the plurality of resistance increasing units 400 will be described.

The resistance increasing unit 400 is a plurality, the outer diameter (d _i ) may vary along the longitudinal direction of the hollow pipe (200).

For example, the resistance increase unit 400, the outer diameter (d _i ) may increase as the inside of the ground in the longitudinal direction of the hollow pipe 200, the other end at the end (outside) of the anchor (filled in soil) End), and the D1 < D2 < D3 < D4 < … It may be a relationship of <Dn.

As another example, a resistance increase unit 400 having a constant outer diameter is coupled along the longitudinal direction of the hollow pipe 200, and a resistance increase unit 400 having a larger outer diameter is coupled after a predetermined distance, where D1 = D2 = D3 <D4 = D5 = D6.

On the other hand, in this case, the proper distance (L _i ) between the resistance increasing unit 400 may also play a role of maximizing the friction force, specifically, the shear resistance increasing portion 400 of the small diameter D1, D2, D3 The spacing between the panels L1 and L2 is small and the spacing is narrow. The spacing of the spacing L3, L4 and L5 of D4, D5 and D6 is relatively large and the spacing can be wide.

Not limited to this example, it may have a relationship of L1 <L2 <L3 <L4 <L5, it is possible to maximize the friction force according to various arrangements.

In addition, for coupling installation of the united hollow pipe 200 of the resistance increasing unit 400, a coupling position marker for coupling with the resistance increasing unit 400 may be formed or displayed on the outer peripheral surface of the hollow pipe 200. .

Meanwhile, the plurality of resistance increasing units 400 may have a ring shape fitted into the outer circumferential surface of the hollow pipe 200.

More specifically, the plurality of resistance increasing units 400 may have a ring shape integrally formed, or a plurality of members may be combined to form a ring shape.

On the other hand, the fixing member 410 for supporting the resistance increasing unit 400 in order to prevent the sliding to the outside in a state where the plurality of resistance increase unit 400 is coupled to the hollow pipe 200 of the hollow pipe 200 It may be additionally installed on the outer circumferential surface.

The fixing member 410 is additionally installed on the outer circumferential surface of the hollow pipe 200 in order to prevent the sliding to the outside in a state where the plurality of resistance increase unit 400 is coupled to the hollow pipe 200 Various configurations are possible as the configuration for supporting the 400.

Here, the fixing member 410 is preferably installed on the outside of the resistance increaser 400 to prevent the resistance increaser 400 from being pushed outward.

Furthermore, the fixing member 410 is more preferably installed in front of and behind the resistance increasing part 400 to prevent relative movement of the resistance increasing part 400 with respect to the hollow pipe 200 by the tensile force.

On the other hand, the fixing member 410, for easy coupling with the hollow pipe 200, may be a clamp, one side may be an annular open.

At this time, the fixing member 410, a fastening hole for bolt fastening may be formed on one side of the open, by coupling the open side through the screw coupling of the bolt 411 to the fastening hole, to the hollow pipe 200 Can be combined.

As another example, the fixing member 410, as shown in Figure 5, may be composed of a combination of semi-circular clamp member, a fastening hole for screw coupling is formed at both ends, the screw coupling of the bolt 411 It may be coupled to the hollow pipe 200 through.

In addition, the fixing member 410 may be fitted to the hollow pipe 200, such as the resistance increase unit 400 described above.

On the other hand, despite the installation of the fixing member 410, the resistance increase unit 400 may be a relative movement of the resistance increase unit 400 with respect to the hollow pipe 200 by the tensile force.

Accordingly, as shown in FIG. 4B, the taper member 430 having an outer circumferential surface inclined at least one of the front and the rear side of the gating and the resistance increase unit 400 may be additionally installed.

For example, the taper member 430 is installed between the resistance increasing unit 400 and the fixing member 410, and one end of the taper member 430 is inserted into the inner circumferential surface of the resistance increasing unit 400 and is based on the longitudinal direction of the hollow pipe 300. As it goes from one end to the other end may be configured to increase the outer diameter.

When the taper member 430 having the structure described above is installed, when the relative movement of the resistance increase unit 400 with respect to the hollow pipe 200 occurs, the taper member 430 is moved toward the inner circumferential side of the resistance increase unit 400. It is pushed in.

In addition, the taper member 430 has a compressive force acting on the outer circumferential surface of the hollow pipe 200 by the compressive force of the inner circumferential surface of the resistance increasing unit 400 and acts as a frictional force to increase the resistance to the hollow pipe 200. ) Can prevent relative movement.

On the other hand, the taper member 430, in order to induce the generation of compression force, it is preferable to use an elastic material such as a ductile metal, synthetic resin.

On the other hand, the resistance increasing unit 400, in order to increase the resistance to the tensile force to the outside when the tension is applied to the tensioning portion 100, the anchor force increasing portion (not shown) further protruded in the radial direction Can be extended.

The anchor force increasing part may protrude in the radial direction of the resistance increasing part 400 to increase the anchor force corresponding to the tension of the tension action part 100.

The anchor force increasing part may be integrally formed with the resistance increasing part 400, and may be formed by being coupled to an outer circumferential surface of the resistance increasing part 400 as an annular ring.

The anchor force increasing part may have a wedge shape in which a radius of the inner side of the drilling hole is smaller than a radius of the opposite side in order to increase the effect of the frictional force.

On the other hand, the steel bar-type acupressure compression type permanent ground anchor according to the present invention, the front end of the hollow pipe 200 is coupled to the tip head 210, the tip head 210 is coupled to the longitudinal direction of the hollow pipe 200, the tension action One end of the portion 200 may further include a tip cap 220 and the like.

The tip head 210 is configured to be coupled in the longitudinal direction to the end of the hollow pipe 200, various configurations are possible.

The front end head 210, the through opening 211 may be formed to pass through one or more cables 130, the cable 130 is penetrated through the through opening 211 is fixedly coupled to the front end cap 220 Can be.

The tip head 210, one end is coupled to the hollow pipe 200, the other end may be coupled to the tip cap 220, it may be by a variety of coupling methods.

For example, the tip head 210, the stepped portion 212 is formed on the coupling portion of the hollow pipe 200 and the tip cap 220, the hollow pipe 200 and the tip in the stepped portion 212 The cap 220 may be fitted to be coupled.

At this time, the step portion 212, the step may correspond to the thickness of the hollow pipe 200.

As another example, the tip head 210 may be formed with a male thread on the stepped portion 212, and a female thread corresponding to the inner circumferential surface of the hollow pipe 200 may be fastened by screwing.

The tip cap 220 is connected to the tip head 210 to form a lower end of the acupressure-type permanent ground anchor according to the present invention, the tip head 210 is extended and coupled in the longitudinal direction of the hollow pipe 200 ) May be combined.

The tip cap 220 may be coupled to the cable 130 connected through the tip head 210.

The cable 130, the coupling member (not shown) may be coupled to the end in order to be coupled to the tip cap 220, the end of the cable 130, the coupling member is coupled to the tip cap 220 inside The cable 130 and the front end cap 220 may be coupled to the fixing unit 221 to be formed.

That is, the end of the cable 130, the wires 110 are extruded and fixed by the coupling member, the coupling member is coupled to the fixing unit 221 formed in the tip cap 220, the tension action portion 100 The tension of the hollow pipe 200 can be transmitted.

At this time, the coupling member and the tip cap 220 may be coupled by a variety of methods, more specifically by a steel clamp.

On the other hand, the steel bar type pressure compression permanent ground anchor according to the present invention having the configuration as described above, in addition to the hollow pipe 200 for forming the anchor force by the frictional force with the ground, is coupled to the hollow pipe 200 wire ( By further providing a plurality of resistance increasing portion 400 to further increase the ground pressure of the ground when the tension is applied to the tension action portion 100 made of 110, by using the frictional force and the ground pressure of the ground The anchor force can be greatly improved.

Hereinafter, a second embodiment of a nut-type acupressure compression type permanent ground anchor according to a second embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The nut-type acupressure-type permanent ground anchor according to the second embodiment of the present invention is different from the configuration of the hollow pipe 200 and the resistance increase unit 400 coupled thereto, so that description of the remaining components is omitted and the hollow pipe ( 200 and the resistance increase unit 400 coupled thereto will be described.

Specifically, the nut-type acupressure-type permanent ground anchor according to the second embodiment of the present invention, as shown in Figures 9 to 17b, a pressure-pressure-type permanent ground anchor is installed through the soil having a slope formed on one side In the, A plurality of wires 110, and tensioning unit 100 consisting of one or more grout hose 120 for performing grouting; A part of the tensioning part 100 is inserted from one end of the tensioning part 100, and is embedded in the earth and sand to the outer circumferential surface to increase the resistance to the tension force to the outside when the tension is applied to the tensioning part 100. A hollow pipe 200 in which the protrusion 230 is formed; The other end of the tension action unit 100 is coupled, the head portion 300 is exposed to the other side of the structure (1); Sequentially disposed along the longitudinal direction of the hollow pipe 200, coupled to the outer side of the hollow pipe 200, to further increase the resistance to the tensile force to the outside when tension is applied to the tension action portion (100) It may include a plurality of resistance increasing unit 400.

10 and 12a, a part of the tensioning part 100 is inserted from one end of the tensioning part 100, and the tensioning part 100 is embedded in the soil. In order to increase the resistance to the tensile force to the outside when the tension is applied to the) as a configuration in which the protrusion 230 is formed on the outer peripheral surface is possible in various configurations.

12A and 12B, the protrusion 230 is formed on the outer circumferential surface of the tension action part 100 and is configured to increase the frictional force of the hollow pipe 200, and various configurations are possible.

The protrusion 230 may be formed at a predetermined interval on the outer circumferential surface of the hollow pipe 200, more preferably may be formed in consideration of the coupling relationship with the resistance increasing unit 400.

For example, the protruding portion 230 is a male screw portion 231, and the resistance increasing portion 400 has a female screw portion 430 corresponding to the male screw portion 231 on an inner circumferential surface thereof, and thus, the hollow pipe 200. Can be screwed on.

That is, the male screw portion 231 is formed on the outer circumferential surface of the hollow pipe 200 and has a spiral structure, and the resistance increasing portion 400 has a female screw portion 430 corresponding to the male screw portion 231 on the inner circumferential surface thereof. Is formed may be screwed to the hollow pipe (200).

Accordingly, the protrusion 230 may be configured to increase the frictional force of the hollow pipe 200 and at the same time may be a coupling means with the resistance increasing unit 400.

In this case, the resistance increase unit 400 is coupled by screw coupling at the end of the hollow pipe 200, can be moved in the longitudinal direction of the hollow pipe 200 through rotation, through which the hollow pipe ( It may be coupled to the screw thread 200).

In order to prevent the movement according to the rotation of the resistance increasing unit 400, the fixing member 410 is coupled to one side, it can prevent the relative movement of the resistance increasing unit 400 with respect to the hollow wave F 200. .

As another example, the protrusion 230 has an annular ring shape on the outer circumferential surface of the hollow pipe 200, as shown in FIGS. 17A and 17B, and the resistance increasing part 400 has a protrusion 230 on the inner circumferential surface. ) May include one or more clamp members 440 and 450 having recesses 441 and 451 formed therein.

In addition, the one or more clamp members 440 and 450 have fastening holes 461 formed at both ends thereof, and a pair of clamp members 440 and 450 are fastened by fastening bolts 460 at both ends thereof. It may be tightly coupled to the outer circumferential surface of the (200).

The clamp members 440 and 450 may be configured in pairs in a semicircular shape, respectively, and fastening holes are formed at both ends of the pair of clamp members 440 and 450, respectively, and are annular by the fastening bolts 460. It can be configured to achieve.

The clamp members 440 and 450 may be formed in various thicknesses, and thus may be fastened to the hollow pipe 200 corresponding to the outer diameter of the resistance increasing unit 400.

In addition, the clamp members 440 and 450 may be more closely coupled to the outer circumferential surface of the hollow pipe 200 by adjusting the fastening strength of the fastening bolt 460.

On the other hand, the resistance increase unit 400, the clamp members 440, 450 further protrude in the radial direction on the outer circumferential surface in order to increase the resistance to the tensile force to the outside when the tension is applied to the tension action portion 100 The anchor force increasing portion (not shown) may be expanded.

The anchor force increasing part may protrude in the radial direction of the clamp members 440 and 450 to increase the anchor force corresponding to the tension of the tension action part 100.

The anchor force increasing part may be integrally formed with the clamp members 440 and 450, and may be formed by being coupled to an outer circumferential surface of the clamp members 440 and 450 as an annular ring.

The anchor force increasing part may have a wedge shape in which a radius of the inner side of the drilling hole is smaller than a radius of the opposite side in order to increase the effect of the frictional force.

Meanwhile, the protrusion 230 may be formed in plural, and the resistance increasing unit 400 may be fastened between the protrusions 230.

That is, the resistance increase unit 400 may be coupled to the position of the hollow pipe 200 between the protrusions 230, and through this, the resistance increase unit 400 may be applied to the friction force acting on the hollow pipe 200. It can be stably supported.

Meanwhile, the plurality of resistance increasing units 400 are sequentially disposed along the longitudinal direction of the hollow pipe 200 similarly to the first embodiment, are coupled to the outer side of the hollow pipe 200, and have a tensioning unit 100. Various configurations are possible as the configuration to further increase the resistance to the tensile force to the outside when the tension is applied to).

In particular, the plurality of resistance increasing parts 400, as shown in Figure 10, the outer diameter from the center of the hollow pipe 200 from the other end of the tension acting portion 200 along the longitudinal direction of the hollow pipe 200 It is desirable to be installed so as to increase to one end.

More specifically, the resistance increase unit 400, as shown in Figure 10 and 12a, may be disposed along the longitudinal direction of the hollow pipe 200, the outer diameter (D _i ) and the spacing (L _i) ) May be arranged in various ways.

The resistance increasing unit 400 may be coupled to the outer circumferential surface of the hollow pipe 200 by various methods.

For example, the resistance increase unit 400, the through-hole having an inner diameter corresponding to the outer diameter of the hollow pipe 200 is formed, can be fitted into the hollow pipe 200 and coupled, more preferably as a clamp By adjusting the radius of the through hole through one end of the bolt, it may be in close contact with the hollow pipe 200.

Hereinafter, an embodiment of maximizing the anchoring force corresponding to the tensile force transmitted from the structure 1 through the method of arranging and coupling the plurality of resistance increasing units 400 will be described.

The resistance increasing unit 400 is a plurality, the outer diameter (d _i ) may vary along the longitudinal direction of the hollow pipe (200).

For example, the resistance increase unit 400, the outer diameter (d _i ) may increase as the inside of the ground in the longitudinal direction of the hollow pipe 200, the other end at the end (outside) of the anchor (filled in soil) End), and the D1 < D2 < D3 < D4 < … It may be a relationship of <Dn.

As another example, a resistance increase unit 400 having a constant outer diameter is coupled along the longitudinal direction of the hollow pipe 200, and a resistance increase unit 400 having a larger outer diameter is coupled after a predetermined distance, where D1 = D2 = D3 <D4 = D5 = D6.

On the other hand, in this case, the proper distance (L _i ) between the resistance increasing unit 400 may also play a role of maximizing the friction force, specifically, the shear resistance increasing portion 400 of the small diameter D1, D2, D3 The spacing between the panels L1 and L2 is small and the spacing is narrow. The spacing of the spacing L3, L4 and L5 of D4, D5 and D6 is relatively large and the spacing can be wide.

Not limited to this example, it may have a relationship of L1 <L2 <L3 <L4 <L5, it is possible to maximize the friction force according to various arrangements.

In addition, for coupling installation of the united hollow pipe 200 of the resistance increasing unit 400, a coupling position marker for coupling with the resistance increasing unit 400 may be formed or displayed on the outer peripheral surface of the hollow pipe 200. .

Meanwhile, the plurality of resistance increasing units 400 may have a ring shape fitted into the outer circumferential surface of the hollow pipe 200.

More specifically, the plurality of resistance increasing units 400 may have a ring shape integrally formed, or a plurality of members may be combined to form a ring shape.

On the other hand, the fixing member 410 for supporting the resistance increasing unit 400 in order to prevent the sliding to the outside in a state where the plurality of resistance increase unit 400 is coupled to the hollow pipe 200 of the hollow pipe 200 It may be additionally installed on the outer circumferential surface.

The fixing member 410 is additionally installed on the outer circumferential surface of the hollow pipe 200 in order to prevent the sliding to the outside in a state where the plurality of resistance increase unit 400 is coupled to the hollow pipe 200 Various configurations are possible as the configuration for supporting the 400.

Here, the fixing member 410 is preferably installed on the outside of the resistance increaser 400 to prevent the resistance increaser 400 from being pushed outward.

Furthermore, the fixing member 410 is more preferably installed in front of and behind the resistance increasing part 400 to prevent relative movement of the resistance increasing part 400 with respect to the hollow pipe 200 by the tensile force.

On the other hand, the fixing member 410, for easy coupling with the hollow pipe 200, may be a clamp, one side may be an annular open.

At this time, the fixing member 410, a fastening hole for bolt fastening may be formed on one side of the open, by coupling the open side through the screw coupling of the bolt 411 to the fastening hole, to the hollow pipe 200 Can be combined.

As another example, the fixing member 410, as shown in Figure 13, may be composed of a combination of semi-circular clamp member, a fastening hole for screwing is formed at both ends, the screw coupling of the bolt 411 It may be coupled to the hollow pipe 200 through.

In addition, the fixing member 410 may be fitted to the hollow pipe 200, such as the resistance increase unit 400 described above.

On the other hand, despite the installation of the fixing member 410, the resistance increase unit 400 may be a relative movement of the resistance increase unit 400 with respect to the hollow pipe 200 by the tensile force.

Accordingly, as shown in FIG. 12B, the taper member 430 having an outer circumferential surface inclined at least one of the front and the rear side of the gating and the resistance increase unit 400 may be additionally installed.

For example, the taper member 430 is installed between the resistance increasing unit 400 and the fixing member 410, and one end of the taper member 430 is inserted into the inner circumferential surface of the resistance increasing unit 400 and is based on the longitudinal direction of the hollow pipe 300. As it goes from one end to the other end may be configured to increase the outer diameter.

When the taper member 430 having the structure described above is installed, when the relative movement of the resistance increase unit 400 with respect to the hollow pipe 200 occurs, the taper member 430 is moved toward the inner circumferential side of the resistance increase unit 400. It is pushed in.

In addition, the taper member 430 has a compressive force acting on the outer circumferential surface of the hollow pipe 200 by the compressive force of the inner circumferential surface of the resistance increasing unit 400 and acts as a frictional force to increase the resistance to the hollow pipe 200. ) Can prevent relative movement.

On the other hand, the taper member 430, in order to induce the generation of compression force, it is preferable to use an elastic material such as a ductile metal, synthetic resin.

Hereinafter, the ground reinforcement method using the acupressure compression type permanent ground anchor according to the present invention having the above configuration will be described in detail with reference to the accompanying drawings.

Ground reinforcement method using acupressure compression type permanent ground anchor according to the present invention, as shown in Figure 18, as a ground reinforcement method using the above-mentioned pressure compression type permanent ground anchor, to form a punched hole by drilling the ground to be reinforced Drilling hole forming step (S1) and; Inserting step (S2) for inserting the tension action portion 100 and the hollow pipe 200 in the drilling hole formed through the drilling hole forming step (S1); An injection step (S3) of injecting the grout material through the grout hose 120 of the tension action part 100; Curing the injected grout material, and may include a coupling step (S4) for coupling the head portion 300 to the other end of the tension action portion (100).

Here, before the inserting step (S2), when the tension is applied to the tensioning unit 100, the plurality of resistance increase unit 400 to further increase the resistance to the tensile force to the outside in the longitudinal direction of the hollow pipe 200 It is preferable to be disposed along the following to be coupled to the outside of the hollow pipe (200).

The drilling hole forming step (S1) is a step of forming a drilling hole by drilling the ground to be reinforced, and may be performed by various methods.

In the drilling hole forming step (S1), not only the hollow pipe 200 and the tensioning part 100 of the acupressure compression type permanent ground anchor are inserted, but the grout to be described below should be injected and filled, so that the drilling hole has a sufficient size. Preference is given to perforations.

The insertion step (S2) is a step of inserting the tension action portion 100 and the hollow pipe 200 into the drilling hole formed through the hole forming step (S1), the hollow pipe 200 and the tension action portion 100 ) Is preferably inserted in the center of the drilling hole.

The insertion step (S2), when inserting the hollow pipe 200 and the tension action portion 100, can be carefully inserted so that the ancillary composition such as corrosion inhibitors are not lost.

The injection step (S3), as a step of injecting the grout material through the grout hose 120 of the inserted tension action portion 100, may be a step of forming a grout in the drilling hole.

The injection step (S3), may be injected through the grout hose 120 to form a grout inside the hollow pipe 200, the hollow pipe 200 and the tension through other external grout hose (not shown) Grout can be formed in the space of the drilled hole between the working part and the ground.

In the coupling step S4, the injected grout material may be cured, and the head part 300 may be coupled to the other end of the tension action part 100.

The coupling step S4 may further include additionally injecting the grout to compensate for some of the lost grout before coupling the head unit 300.

In the coupling step (S4), for coupling the head portion 300 and the tension action portion 100, a coupling member may be additionally installed, more specifically, a wedge, a grip type coupling may be used. .

On the other hand, after the coupling step (S4), the tensioning step of the acupressure compression type permanent ground anchor may be further included.

In the tensioning step, a tensioner connected to a hydraulic high pressure pump or the like may be installed, and the tensioner may be connected to the tension action part 100 to measure the pressure and the amount of tension.

Since the above has been described only with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention, as is well known, should not be construed as limited to the above embodiments, the present invention described above It will be said that both the technical idea and the technical idea which together with the base are included in the scope of the present invention.

1: Structure 100: tensioning part
200: hollow pipe 300: head portion
400: increase resistance

Claims (13)

A compression-type permanent ground anchor is installed through the soil is formed on one side, the tension action portion 100 consisting of a plurality of wires 110, one or more grout hose 120 for performing grouting; A part of the tensioning part 100 is inserted from one end of the tensioning part 100 and is embedded in the soil to increase the resistance to tensile force to the outside when the tension is applied to the tensioning part 100. Hollow pipe 200 and; In the ground reinforcement method using the pressure-compression type permanent ground anchor is coupled to the other end of the tension action part 100, the head portion 300 is exposed to the other side of the earth and sand,
A drilling hole forming step (S1) of forming a drilling hole by drilling the ground to be reinforced;
An insertion step (S2) of inserting the tension action part (100) and the hollow pipe (200) into the drilling hole formed through the drilling hole forming step (S1);
An injection step (S3) of injecting grout material through the grout hose 120 of the tension action part 100;
Curing the injected grout material, and includes a coupling step (S4) for coupling the head portion 300 to the other end of the tension action portion 100,
Before the insertion step (S2), the length of the hollow pipe 200 has a plurality of resistance increasing portion 400 to further increase the resistance to the tensile force to the outside when the tension is applied to the action portion 100 Ground reinforcement method using a pressure-pressure permanent ground anchor, characterized in that arranged in sequence along the direction coupled to the outside of the hollow pipe (200). The method according to claim 1,
The hollow so that the outer diameter from the center of the hollow pipe 200 increases the plurality of resistance increasing parts 400 from one end to the other from the other end of the tension action part 200 along the longitudinal direction of the hollow pipe 200. Ground reinforcement method using a pressure-pressure permanent ground anchor, characterized in that coupled to the outside of the pipe (200). The method according to claim 2,
The plurality of resistance increase units 400,
Ground reinforcement method using a pressure-pressure permanent ground anchor, characterized in that it has a ring shape fitted into the outer peripheral surface of the hollow pipe (200). The method according to claim 3,
The plurality of resistance increase units 400,
A ground reinforcement method using an acupressure compression type permanent ground anchor, characterized in that it has an integrally formed ring shape, or a plurality of members are combined to form the ring shape. The method according to claim 1,
The hollow pipe 200,
Ground reinforcement method using a pressure-compression type permanent ground anchor, characterized in that the protrusion 230 is formed on the outer circumferential surface in order to further increase the resistance to the tensile force to the outside when the tension is applied to the tension action portion 100 . The method according to claim 5,
The protruding portion 230 is a male screw portion 231 having a spiral structure on an outer circumferential surface of the hollow pipe 200,
The resistance increase part 400, the internal pressure is formed with a female screw portion 430 to be screwed to the male screw portion 231, acupressure, characterized in that it comprises a nut member for screwing the hollow pipe 200 Ground reinforcement method using compression type permanent ground anchor. The method according to claim 5,
The protruding portion 230 has an annular ring shape on the outer peripheral surface of the hollow pipe 200,
The resistance increase unit 400, the pressure-sensitive compression-type permanent ground anchor, characterized in that it comprises at least one clamp member (440, 450) formed with grooves (441, 451) to insert the protrusion 230 on the inner peripheral surface Ground reinforcement method using. The method according to any one of claims 1 to 7,
The plurality of resistance increase units 400,
Using an acupressure compression type permanent ground anchor, characterized in that the outer diameter from the center of the hollow pipe 200 increases from one end to the other end of the tension action portion 200 along the longitudinal direction of the hollow pipe 200 Ground reinforcement method. The method according to claim 8,
The hollow pipe 200 includes a fixing member 410 for supporting the resistance increase unit 400 in order to prevent the resistance increase unit 400 from being pushed outward in a state in which the plurality of resistance increase units 400 are coupled to the hollow pipe 200. Ground reinforcement method using acupressure compression permanent ground anchors, characterized in that additionally installed on the outer circumferential surface. The method according to any one of claims 1 to 7,
The head part 300,
Manshon 310 is coupled to the tension action unit 100, penetrated through the earth and sand, to form a male screw portion 311 on the outer circumferential surface,
Acupressure plate 320 coupled to the manshon 310 and in close contact with the earth and sand;
Ground reinforcement method using a pressure-pressure-type permanent ground anchor, characterized in that it comprises a reinforcing nut (330) coupled to the pressure plate (320) in close contact with the upper surface side of the mansion (310). The method according to claim 10,
The head part 300,
Ground reinforcement method using a pressure-pressure permanent ground anchor, characterized in that coupled to the end of the manshon 310, a part of the manshon 310 and the protective cap 340 to protect the reinforcing nut 330. . The method according to any one of claims 1 to 7,
Coupled to the first end of the hollow pipe 200 in the longitudinal direction of the hollow pipe 200, the front end head 210 is coupled to one end of the plurality of wires 110 of the tension action part 100 Ground reinforcement method using acupressure compression type permanent ground anchor characterized in that. The method according to claim 12,
Ground using a pressure-pressure-type permanent ground anchor, characterized in that the tip cap 220 to cover the end portion of the tip head 210 is coupled to one end of the tension-actuating part 200 of the tip head (210). Reinforcement method.

Images