KR100880690B1 - The anchor method which uses the ground anchor - Google Patents

Abstract

A ground anchor and a ground anchor method using the same are provided to secure required tensile force and to form a stable reinforcement structure by having sufficient anchor force, and to perform construction work more quickly, stably and economically. A ground anchor method of construction comprises the steps of inserting a tensile steel wire(101) including an anchor to a perforated hole and injecting grout, thereby applying tensile force to the tensile steel wire and occurring resistance by friction between the grout of an anchor(100) and the anchor, and guiding a pressure wedge(50) contacted with grout at the front of an anchor to receive direct frictional resistance along an incline of a pressure device(40) with the pressure of grout, advancing and pressurizing an internal wall of the perforated hole simultaneously to be applied with pressure force additionally and anchored closely.

Description

Ground anchor and the anchor method using the same

The present invention relates to a ground anchor for reinforcing by introducing a tensile force to the ground or structure, and an anchor method using the same. More specifically, it is easy to fasten and dismantle the tension member, permanently through the use of the optional fixing wedge The grout can be formulated or removed, and after the grout is injected into the punched hole, the pressurized member presses the inner wall of the punched hole by frictional resistance between the pressurizing member constituting the anchor and the grout when the tensile force is introduced into the tensile steel wire. The present invention relates to a ground anchor and an anchoring method using the same, by which the anchor can be additionally fixed so that the anchor can be tightly set up so that the installation of the ground anchor can be performed quickly and conveniently.

In general, when the civil works of industrial complexes such as residential complexes, industrial complexes, railways, highways, tunnels, artificial steep slopes are formed due to natural slopes or excavation.

Naturally and artificially formed slopes are exposed to the risk of cutting and collapse due to various factors such as earth pressure, wind pressure, water pressure, and earthquake.

Therefore, various ground and slope reinforcement methods, such as soil nailing, rock bolting, and ground anchors, are used to prevent cutting and collapse of the slope.

Among them, ground anchors are used not only for reinforcing the ground but also as reinforcements for supporting structures such as building bridges, and in detail, the anchor body is formed at the tip of the tension member embedded in the ground by the injection of cement paste or grouting. The anchor is a state in which the tension member is mechanically connected to the structure through the head of the tension member and the anchor body, and the force applied to the tension member is transferred to the base plate through the anchor body and the grouting. It is carried out.

However, in the conventional ground anchors, the anchoring force is mostly introduced only by the frictional force between the ground and the grout, and the structure of the anchor itself is complicated and it is inconvenient to use a separate anchor when permanently removing or removing the tensile steel wire. There is a problem. In addition, when the moisture penetrates into the gap of the ruptured grout, the anchor body and the tensile steel have a poor waterproofing treatment, resulting in the loss of the anchor force due to the corrosion of the anchor body and the tensile steel, and thus the function of the ground anchor is lost. It is occurring.

 In order to solve the above problems, the present invention forms a punched hole for inserting the anchor coupled to the tensile steel when reinforcing the soft ground, insert a tensile steel including the anchor into the punched hole, and then inject the grout to tension When the tensile force is introduced into the steel wire, the pressing member is pushed toward the inner wall of the drilled hole by the frictional resistance between the pressurizing member and the grout formed in the anchor and pressurizes the inner wall, and the anchor itself can be tightly fixed to the inner wall of the drilled hole. The purpose of the present invention is to provide a ground anchor with a waterproof structure to prevent corrosion and to complete the ground reinforcement work more stably and economically.

In order to achieve the above object, the present invention has a female screw portion formed on the upper and lower sides of the outer circumferential surface, and several taper holes are formed in the center through the upper and lower portions so that the fixing wedges fixing the end portions of the tensile steel wire are coupled at the lower side. With a fixed member,

 A male thread portion is formed on the upper inner circumferential surface to be screwed with the female screw portion of the lower side of the fixing member, and a lower protection to prevent corrosion of the fixing wedge that fixes the tensile steel wire coupled to the lower portion of the fixing member at the lower side of the fixing member. With the cap,

On the upper inner side of the fixing member, a male screw portion is formed on the lower inner circumferential surface of the fixing member to prevent corrosion of the fixing wedge coupling the tensile steel wire, and the center of the rubber packing is inserted into the upper inner portion. Perforated upper protective cap,

Rubber packing and several insertion holes are penetrated and inserted into the upper inside of the upper protective cap to perform a waterproof function,

The outer circumferential surface of the upper side is tapered, an O-ring groove is formed on the middle side of the outer circumferential surface, a thread is formed on the inner upper side, and a stepped portion is formed on the inner lower side to fix the end portion of the tensile steel wire divided into three pieces. However, the fixing wedge and formed to be coupled to the upper side of the inner step including a conical pin,

Two triangular inclined surfaces are formed, and the acupressure tool with several through holes drilled into the inclined surface is seated with the upper outer rim of the upper protective cap. A pressurizing member to which the pressurized wedge to be placed is coupled to correspond to the inclined surface of the acupressure port,

The ground anchor is composed of a rubber sleeve formed on the outer circumferential surface of the pressing member and the upper protective cap to prevent the pressing wedge from being deviated from the inclined surface of the bearing and at the same time to prevent the pressing member from being separated from the upper protective cap. There is a characteristic.

According to the construction of the ground anchor of the present invention, the anchor itself is stably settled in the perforation hole, thereby increasing the coupling force between the ground anchor and the filled grout, thereby exhibiting sufficient anchoring force, thereby securing a required tensile force to form a stable reinforcement structure. It is a very useful invention that is expected to have a much faster, more stable and economical construction, and has a very high expected value.

The present invention forms a drilling hole for inserting the anchor anchored to the tensile steel when reinforcing the soft ground, inserting the tensile steel wire including the anchor into the drilling hole, injecting grout into the anchor when introducing the tensile force into the tensile steel wire With the frictional resistance between the pressure member and the grout, the pressure member is pushed toward the inner wall of the drilled hole and pressurizes the inner wall, and the anchor itself can be tightly fixed to the inner wall of the drilled hole. It is characterized in that the ground anchors formed a waterproof structure for.

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

1 is an exploded perspective view showing an embodiment of the present invention, Figure 2 is a sectional view showing a construction state of the present invention, Figures 3 to 5 is a sectional view showing a fixing process of the present invention, 6 to 7 is a cross-sectional view showing a process of removing the tensile steel according to the present invention, Figure 8 shows a partially separated perspective view showing another embodiment of the present invention, Figure 9 is a fixing of another embodiment of the present invention It shows a cross-sectional view showing the state.

In the present invention, the male thread portion 11 is formed on the upper and lower sides of the outer circumferential surface, and several taper holes 12 are formed at the center such that the fixing wedge 70 for fixing the end of the tensile steel wire 101 is coupled at the lower side. A fixing member 10 formed through the upper and lower portions,

A female screw part 81 is formed on the upper inner circumferential surface of the fixing member 10 to be screwed with the lower male screw part 11 of the fixing member 10, and from the lower side of the fixing member 10 to the lower part of the fixing member 10. A lower protective cap 80 to prevent the fixing wedge 70 fixing the tensile steel wire 101 to be corroded;

It prevents the corrosion of the fixing wedge (70) for coupling the tensile steel wire 101 in the upper side of the fixing member 10, and screwed with the upper male portion 11 of the fixing member 10 on the lower inner peripheral surface The upper threaded portion 21 is formed, the upper protective cap 20 through which the center is penetrated so that the rubber packing 30 is inserted into the upper inside,

Several insertion holes 31 are penetrated to penetrate the rubber packing 30 which is inserted into the upper inside of the upper protective cap 20 to perform a waterproof function, and

The outer peripheral surface of the upper side is formed to be tapered (71), the O-ring groove (74) is formed on the middle side of the outer peripheral surface, a screw thread (72) is formed on the inner upper side, and the stepped portion (73) is formed on the inner lower end. The fixing wedge 70 is divided into three pieces and fixed to the end portion of the tensile steel wire 101, the fixing wedge 70 formed to be coupled to the top of the inner stepped portion 73, including a conical pin 75,

Two triangular inclined surfaces 42 and 42a are formed, and the acupressure hole 40 through which several through holes 41 are drilled by the inclined surface 42 is seated on the upper outer edge of the upper protective cap 20. The above-mentioned guide groove 51 penetrates through, and the inclined surface 52 is formed on the inner side, and the pressing wedge 50 which is settled on the inclined surfaces 42 and 42a of the acupressure tool 40 is the inclined surface of the acupressure tool 40 ( A pressing member 60 formed by correspondingly coupling to 42 and 42a,

Pressurizing member 50 and the upper protection to prevent the pressing wedge 50 from being separated from the inclined surface of the acupressure port 40 and at the same time to prevent the acupressure port 40 from being separated from the upper protective cap 20 It is characterized in that the rubber sleeve 61 formed to fit on the outer circumferential surface of the cap 20.

Meanwhile, in the present invention, the tensile steel wire 101 coated with the cover 101a, the blanket 201, the pressure plate 202, and the fixing hole 203 for fixing the tensile steel wire 101 at the inlet of the drilling hole 300 are provided. Is commonly used and will not be described in detail.

In the present invention configured as described above, when the anchor 100 including the tensile steel wire 101 is inserted into the inner side of the drilling hole 300 and the grout 200 is injected, a tensile force is applied to the tensile steel 101 at the same time. As shown in FIG. 4 due to the tensile force applied, resistance force due to friction between the grout 200 and the anchor 100 is generated, and in contact with the grout 200 at the front end of the anchor 100 to receive direct frictional resistance. The pressing wedge 50 is guided along the inclined surface of the acupressure hole 40 by the pressure of the grout 200, and tightly fixed while pressing the inner wall of the drilling hole 300 to open the anchor 100 itself. 300) The stable reinforcement structure is secured by securing the required tensile force by stably fixing the inside to increase the coupling force between the ground anchor 100 and the grout 200 to be filled with the introduction of bearing pressure. Forming It would be a help.

Hereinafter, the configuration of the present invention will be described in more detail along with the fixing process.

Looking at the assembly process of the present invention, the male screw portion 11 formed on the outer peripheral surface of the upper side of the fixing member 10 is coupled by screwing the female screw portion 21 of the lower inner side of the upper protective cap 20.

When the fixing member 10 is coupled to the lower side of the upper protective cap 20, the rubber packing 30 is inserted into the inner side of the upper protective cap 20 to be fixed at the lower side of the upper protective cap 20. The love packing 30 is coupled to the upper surface of the member 10 to be seated. At this time, it is preferable to insert several insertion holes 31 drilled in the rubber packing 30 to coincide with several taper holes 12 formed in the fixing member 10.

After the rubber packing 30 is inserted into the upper inside of the upper protective cap 20, the two pressing wedges 50 are coupled to the inclined surface of the acupressure tool 40 constituting the pressing member 60 to correspond to each other, The rubber packing 30 is seated in contact with the upper edge of the upper protective cap 20 into which the rubber packing 30 is inserted in contact with the bottom surface of the acupressure port 40, so that the pressing member 60 has an upper protective cap ( 20) without being separated, the rubber sleeve 61 is integrally fitted to the upper protection cap 20 from the pressing member 60 so as to be integrally covered.

On the other hand, the through-hole 41 formed of the shiatsu port 40 is also acupressure to the insertion hole 31 of the rubber packing 30 is inserted into the upper protective cap 20 at the time of seating the upper protective cap 20 It is preferable that the through holes 41 of the spheres 40 are matched to each other.

When the pressing member 60 is completed by the rubber sleeve 61, the coupling is completed to the upper protective cap 20, inserting the end of the coated tensile steel wire 101 into the guide groove 51 formed in the pressing wedge 50 , Penetrating the hole 41 of the acupressure hole 40 and the insertion hole 31 of the rubber packing 30 and the taper hole 12 of the fixing member 10,

In order to fix the tensile steel wire 101 protruding through the tapered hole 12 of the fixing member 10, the fixing wedge 70 was coupled to the end portion of the tensile steel wire 101 to insert the tensile steel wire 101. The taper 71 portion formed on the upper side of the fixing wedge 70 by being pulled in the opposite direction is inserted into the taper hole 12 penetrated from the bottom of the fixing member 10, and the fixing wedge 70 is tapered hole 12. Due to being coupled to the tensile steel wire 101 is fixed and coupled to the fixing member (10).

The fixing wedge 70 coupled to the tensile steel wire 101 to fix the tensile steel wire 101 is divided into three pieces, and the tensile steel wire 101 is coupled to the end by assembling three pieces at the end, and the fixing member ( 10 is inserted into the taper hole 12, the upper side of the outer peripheral surface of the fixing wedge 70 is formed to be tapered (71) to press and fix the tensile steel wire 101, the screw thread 72 on the inner upper portion ) Is formed to prevent the tensile steel wire 101 from slipping from the fixing wedge 70 when the tensile force is applied to the tensile steel wire 101.
On the other hand, when the fixing wedge 70 is assembled into a tensile steel wire 101, the fixing wedge 70 made of three pieces is assembled in a form surrounding the end of the tensile steel wire 101, the tensile steel wire 101 is O-ring of the rubber material in the O-ring groove 74 formed in the outer peripheral surface of the lower side of the fixing wedge 70 until it is fixed by inserting the combined fixing wedge 70 into the taper hole 12 of the fixing member 10 ( Filling 76 prevents the fixing wedge 70 from being separated from the tensile steel wire 101, and after the fixing wedge 70 is coupled to the fixing member 10, the tensile steel wire 101 can be easily removed. O-ring 76 is preferably removed with a blade so as to be able to. Since the use of the O-ring 76 as a fixing means is a configuration that can be easily understood by those skilled in the art from the general technology, a detailed description and illustration of the operation and effect thereof will be omitted.

In addition, by assembling the three pieces of conical pin 75 is inserted into the upper portion of the stepped portion 73 to be formed on the lower side of the fixing wedge 70 when combined with the tensile steel wire 101 fixing wedge 70 The conical pin 75 is interposed between the end portion and the lower side step portion 73 of the tensile steel wire 101 is fixed to the inside of the configuration, each tensile steel wire 101 is anchored by the same assembly method Combined with (100).

When the tensile steel wire 101 by the fixing wedge 70 is completed to the fixing member 10, the outer circumferential surface of the fixing member 10 to protect the coupling portion between the tensile steel wire 101 and the fixing wedge 70 The assembly of the present invention is completed by screwing the upper inner female screw portion 81 of the lower protective cap 80 into the lower male screw portion 11.

In the present invention assembled as described above, the anchor including the tensile steel wire 101 is inserted into the lower end of the drilling hole 300 to fill the grout 200, and then settled. Hereinafter, the fixing process of the present invention will be described in detail. Let's look at it.

When the operator inserts the anchor 100 of the present invention coupled to the end of the tensile steel wire 101 to the lower end from the inlet of the drilling hole 300, the acceleration acceleration and the tensile steel wire 101 and the anchor 100 by the operator The lower surface of the lower protective cap 80 constituting the anchor is stopped when the bottom surface of the drilling hole 300 comes into contact with the bottom surface by the self weight.

The drilling hole 300 is to be drilled so that the lower end is inclined low relative to the inlet portion as shown in Figure 2 will be able to easily insert the tensile steel wire 101 and the anchor 100.

When the insertion of the anchor including the tensile steel wire 101 at the lower end of the drilling hole 300 is completed, the grouting device (not shown) is operated to fill the grout 200 into the inside of the drilling hole 300 through the supply hose. .

After the filling of the grout 200 is completed and cured in the drilling hole 300, the tensile steel wire protruding toward the inlet side by installing the bracket 201, the pressure plate 202, and the fixing unit 203 at the inlet of the structure. (101) By fixing the tip portion and applying a tensile force to anchor the anchor 100 to the interior of the drill hole 300 closely.

Here, when a tensile force is applied to the tensile steel wire 101 at the inlet of the drilling hole 300 in the state where the grout 200 is filled in the drilling hole 300, the anchor inserted into the inner lower end of the drilling hole 300 is provided. Pulled by the tensile steel wire 101, the pressure of the grout (200) filled with the anchor is generated by the pull force is drawn to generate a resistance due to the friction between the anchor and the grout (200).

Accordingly, a structure in which the anchor 100 is tightly fixed to the inner wall surface of the drilling hole 300 by inducing a pulling force applied by the tensile force and frictional resistance due to the pressure of the grout 200 filled into the drilling hole 300. When the tensile force is applied to the tensile steel wire 101 to form it, the anchor 100 receives the pressure directly received from the grout 200 and the pressing member 60 moves to the upper end of the anchor 100 so as to use frictional resistance. It is made up.

The pressure wedge 50 correspondingly coupled to the acupressure port 40 through the generated frictional resistance is guided along the inclined surface of the acupressure port 40 by the pressure of the grout 200, and the inside of the drilling hole 300. While pressing the side wall, the ground pressure is further introduced and tightly settled.

The acupressure port 40 is to press the pressure wedge 50 by the pulling force pulled, the pressure wedge 50 is a pressure sphere 40 which is in contact with the inclined surfaces at the same time the one side receives the pressure of the grout 200 directly By pressing it is advanced to the inner wall of the drilling hole 300.

The pressure wedge 50 is guided to the inclined surface of the acupressure hole 40 and the rubber slip rib 61 which was fitted to prevent the release of the pressure member 60 when assembling the anchor when advancing into the inner wall of the drilling hole 300. ), The pressure wedge 50 presses the inner wall of the punching hole 300 due to the tensile force applied, and the rubber sleeve 61 is broken or torn so that the press wedge 50 is fixed to the inner wall of the punching hole 300. It will not interfere.

In addition, the guide groove formed in the pressing wedge 50 passes through the pressing wedge 50 and is not disturbed by the tensile steel wire 101 coupled and fixed to the fixing member 10. It is to be tightly fixed to anchor the anchor 100 to stably reinforce the ground.

The upper and lower protective caps 20 and 80 constituting the anchor and the rubber packing 30 are waterproof to prevent corrosion of a portion where the end of the tensile steel wire 101 is fixed and coupled by the fixing wedge 70. It is formed.

On the other hand, the anchor 100 is settled and applied sufficient tensile force to complete the curing of the grout 200 is separated from the anchor 100 from the drilling hole 300 to remove the tensile steel wire 101 in Figure 6 to 7 As shown, by pushing the tensile steel wire 101 toward the anchor, the end of the tensile steel wire 101 is pushed down while pushing the cone pin 75 included in the fixing wedge 70, and at the same time the cone pin 75 is fixed While hitting the stepped portion 73 formed on the lower side of the wedge 70, the lower side where the stepped portion 73 of the fixing wedge 70 is opened and at the same time, the fixing wedge 70 itself is a tapered hole of the fixing member 10. The inner diameter of the fixing wedge 70 which fixed the tensile steel wire 101 is separated from the predetermined interval from the wider, so that the tensile steel wire 101 can be easily and conveniently removed.

In the configuration of the present invention, the configuration of the fixing wedge 70 for coupling the tensile steel 101 is to be modified to a configuration for permanent use of the tensile steel 101 as shown in Figure 8 and 9, The outer peripheral surface of the upper side is formed to be tapered 91, the O-ring groove 93 is formed on the outer peripheral surface, and constitutes a permanent fixing wedge 90 formed with a thread 92 on the inner upper, the permanent Fixing wedge 90 is fixed to the end of the tensile steel wire 101, the tensile steel wire 101 is coupled to the anchor 100 is permanently coupled to be configured to be used when reinforcing the ground.

That is, it is configured to perform a removable or permanent ground anchor method through the selective use of the fixing wedge (70,90).

1 is an exploded perspective view showing an embodiment of the present invention

2 is a cross-sectional view showing a construction state of the present invention

3 to 5 are cross-sectional views showing the fixing process of the present invention

6 to 7 is a cross-sectional view showing a process of removing the tensile steel in accordance with the present invention

8 is a partially separated perspective view showing another embodiment of the present invention

9 is a sectional view showing a fixing state of another embodiment of the present invention

<Explanation of symbols for the main parts of the drawings>

300: drilling hole 200: grout 100: anchor 101: tensile steel wire

90: permanent fixing wedge 80: lower protective cap 81: male thread

70: fixing wedge 71: taper 72: thread 73: stepped portion

74: O-ring groove 75: Conical pin 76: O-ring

60: pressure member 61: rubber sleeve

50: pressure wedge 51: guide groove 52: inclined surface

40: acupressure hole 41: through hole 42: inclined surface

30: rubber packing 31: insertion hole

20: upper protective cap 21: male thread

Reference Signs List 10 fixed member 11 female thread portion 12 tapered hole

Claims (3)

In constructing ground anchors, Male thread portion 11 is formed on the upper and lower sides of the outer circumference, and several taper holes 12 are formed at the center so that the fixing wedge 70 for fixing the end portion of the tensile steel wire 101 is engaged at the lower side. A fixing member 10 formed therethrough,  A female thread part 81 is formed on the upper inner circumferential surface of the fixing member 10 to be screwed with the lower male thread part 11 of the fixing member 10, and is coupled to the lower part of the fixing member 10 at the lower side of the fixing member 10. A lower protective cap 80 for preventing the fixing wedge 70 fixing the tensile steel wire 101 from being corroded; It prevents the corrosion of the fixing wedge (70) for coupling the tensile steel wire 101 in the upper side of the fixing member 10, and screwed with the upper male portion 11 of the fixing member 10 on the lower inner peripheral surface The upper threaded portion 21 is formed, the upper protective cap 20 through which the center is penetrated so that the rubber packing 30 is inserted into the upper inside, Several insertion holes 31 are penetrated to penetrate the rubber packing 30 which is inserted into the upper inside of the upper protective cap 20 to perform a waterproof function, and The outer peripheral surface of the upper side is formed to be tapered (71), the O-ring groove 974 is formed on the middle side of the outer peripheral surface, a screw thread (72) is formed on the inner upper side, and the stepped portion (73) is formed on the inner lower side. , Conical pin 75 is provided between the end portion and the stepped portion 73 of the tensile steel wire 101 which is interposed inward to remove the tensile steel wire 101, divided into three pieces, the tensile steel wire 101 A fixing wedge 70 for assembling at an end portion of the cuff) and filling the O-ring 76 with an O-ring groove 74 to insert the taper hole 12 of the fixing member 10 to fix the tensile steel 101. Two triangular inclined surfaces 42 and 42a are formed, and the acupressure hole 40 through which several through holes 41 are drilled by the inclined surface 42 is seated on the upper outer edge of the upper protective cap 20. The above-mentioned guide groove 51 penetrates through, and the inclined surface 52 is formed on the inner side, and the pressing wedge 50 which is settled on the inclined surfaces 42 and 42a of the acupressure tool 40 is the inclined surface of the acupressure tool 40 ( A pressing member 60 formed by correspondingly coupling to 42 and 42a, Pressurizing member 50 and the upper protective cap to prevent the pressing wedge 50 from being separated from the inclined surface of the acupressure port 40 and at the same time to prevent the acupressure port 40 from being separated from the upper protective cap 20 Ground anchor, characterized in that consisting of a rubber sleeve (61) formed to fit on the outer circumferential surface (20). The fixing wedge 70 for fixing the tensile steel wire 101, the upper outer peripheral surface is formed to be tapered 91, the outer ring surface is formed with an O-ring groove 93, the inner upper Permanent fixing wedge 90 is formed with a thread (92) Ground anchor, characterized in that configured to perform the removable or permanent ground anchor method through the selective use of the fixing wedge (70,90). In the ground anchoring method of reinforcing the soft ground using a ground anchor, After inserting the tensile steel wire 101 including the anchor into the drilling hole 300, When the grout 200 is injected to introduce a tensile force into the tensile steel wire 101, a resistance force is generated due to the friction between the grout 200 formed in the anchor 100 and the anchor 100. The pressing wedge 50, which is in contact with the grout 200 at the front end of the anchor 100 and is subjected to direct frictional resistance, is guided along the inclined surface of the acupressure port 40 by the pressure of the grout 200, and is simultaneously drilled out. The grout is filled with the ground anchor 100 by stably anchoring the anchor 100 itself to the inside of the drilling hole 300 by pressurizing the inner wall of the hole 300 while additionally introducing the ground pressure. The ground anchoring method, characterized by forming a stable reinforcement structure by increasing the coupling force between the 200) can exhibit sufficient anchoring force, secure the required tensile force.

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