KR100881901B1 - Steel wire removal type ground anchor - Google Patents

Abstract

A ground anchor for dismantlement of a tensile member is provided to facilitate tension displacement work and reduce the number of parts used for the work. A ground anchor for dismantlement of a tensile member comprises a housing(20) having an insertion hole in which a tensile member(1) is inserted and a guide surface, a wedge(40) comprised of a plurality of wedge pieces(44) moved along the guide surface, an actuating member(60) moving the wedge back, and an actuator(70) having a tensile member receiving groove(76).

Description

Steel wire removal type ground anchor

The present invention relates to a tension member dismantling type ground anchor, and more specifically, the wedge that asks the tension member when the tension force is released to pull the tension member is automatically retracted, and at the same time the dismantling work of the tension member can be made easier, and the construction work is completed When the tension member is rotated after the wedge is retracted, the force for the tension member is automatically released, and thus the tension member dismantling work relates to a tension member dismantling type ground anchor.

In general, ground anchors (also called earth anchors) are used to support earthwork walls that are constructed to prevent settlement of unexcavated ground during excavation work for underground structures in civil or construction work. Ground anchors include permanent installation anchors that leave the tension material intact after installation and tension removal type ground anchors that remove the installed tension material.

In this case, in order to install a tension member for the construction of structures such as underground structures (for example, the subway), a method of installing an anchor body by forming an anchor hole in the ground of another site other than the construction site is adopted. If the tension member is left on a site owned by another person, there are various problems such as a complaint, and so many of the so-called tension member dismantling ground anchors are used to remove the tension material after construction is completed. There is a situation.

In the case of such a tension member-removable ground anchor, anchor holes are formed into the ground through the structure, and the anchor material coupled with the ground anchor is inserted into the anchor holes to be fixed with cement grout, and then the tensile material drawn out is tensioned separately. The outer side of the structure is pulled outward to the structure by fastening the structure to the ground by applying a large tensile load.

For example, at the subway construction site, a plurality of H beams serving as supporting structures in the excavated ground are installed side by side in a vertical direction, and a earth wall (commonly referred to as a retaining wall), which is a structure, is disposed between the H beams. After anchoring, anchor hole is formed in the excavated ground, and the ground anchor with the tension material is inserted into the anchor hole formed in the ground, and then the ground anchor is fixed by filling and curing the anchor hole with the grout (concrete). . Subsequently, when the tension member is pulled by a separate tensioner and coupled to the structure's earth wall in a state where a large tensile load is applied, the earth wall is fixed by the tension member to prevent the earth wall from being collapsed.

However, the conventional tension member dismantling type ground anchor is a structure that does not automatically remove the tension member even after removing the tensile force of the tension member after completion of the construction of the structure at the construction site, there is a disadvantage in that the tension member dismantling work, etc. Since it is necessary to dig up the buried surrounding ground and remove the tension member, it is inefficient in many ways, such as troublesome and time-consuming dismantling of the tension member.In the case of a product configured to remove the tension member relatively smoothly when releasing the tension force of the tension member There is a disadvantage that the overall structure is complicated, which leads to a high product cost.

The present invention is to solve the problems as described above, the object of the present invention is to release the tension force to pull the tension member, the wedge was fixed by biting the tension member retracted by the elastically restoring force of the reverse operation member dismantlement of the tension member The tension member rotation operation can be made more easily, and when the tension member is rotated after completion of the construction of the construction site, the wedge fixing the tension member is reliably retracted and releases the force to apply the tension member. It is to provide a new tensioning material dismantling ground anchor that can ensure reliability during dismantling.

According to the present invention for realizing this object, an insertion hole 22 into which the tension member 1 enters is formed at one end in the longitudinal direction, and a guide surface 24a is formed therein, which narrows toward the insertion hole 22. The tension member is formed along the guide surface 24a of the housing 20 by being provided with a housing 20 and a plurality of wedge pieces 44 formed on the inner side of the guide surface 24a of the housing 20 and having tapered outer surfaces thereof. 1) a wedge 40 press-contacted or spaced apart from the surface of 1), and a reverse actuating member 60 which retracts the wedge 40 when the tension force acting on the tension member 1 is built in the housing 20 and At the proximal end of the wedge 40, the coil spring 50 provided in the housing 20 and the spiral groove 72 formed at the circumferential portion thereof are coupled to the coil spring 50 so as to be rotatable and slidable. Is connected to the rear end of the 40 and the tension member (1) At the distal end facing the end of the) is provided a tension release type ground anchor, characterized in that it comprises a wedge retractor 70 is formed with a tension member receiving groove (76).

The present invention has the effect of releasing the pulled tension of the tension member, by reversing the wedge while being restored to the original by the elastic force of the reverse operation member itself to facilitate the rotation operation of the tension member. In other words, by performing the rotation operation of the tension member to perform the operation of dismantling the tension member by reversing the wedge by the wedge retractor, in the present invention, when the tension force applied to the tension member is released, the reverse operation member is automatically restored to its original state. By automatically reversing the wedge, the wedge is first released from the inclined guide surface of the housing, so that the tension member rotation operation can be facilitated later, and at the same time, the tension member disassembly operation due to the tension member rotation operation is more easily performed. There is.

In addition, the present invention, when the wedge is reversed by the reverse operating member is rotated in one direction in the state that is automatically spaced from the guide surface inside the housing when the wedge reverse actuator is rotated backward along the coil spring by the spiral groove around the wedge Further retraction allows the wedge to completely release the force it has applied to the tensioner, and in this state, simply pulling out the tensioner can simply dismantle the tensioner, making the tensioner disassembly easier and faster. Relatively few parts for smooth tensile dismantling work, the overall structure has a simple effect.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. 1 is an exploded perspective view showing a first embodiment of the present invention, Figure 2 is a perspective view showing a state in which the wedge and the reverse operation member shown in Figure 1 is coupled, Figure 3 is a wedge reverse actuator shown in Figure 1 4A through 4E are cross-sectional views illustrating an internal structure and an operating state of the present invention.

As shown, the present invention has a built-in wedge 40 for biting or releasing the tension member 1 in the interior of the housing 20, the coil spring 50 between the housing 20 and the proximal end of the wedge 40 It is installed, the wedge reverse actuator 70 is coupled to the coil spring 50, the wedge 40 is configured to be reversed by the reverse operation member 60, the reverse operating member when the tension force of the tension member 1 is released The wedge 40 is first spaced apart from the inclined guide surface of the housing 20 by 60, and then the wedge 40 is further retracted by the wedge reverse actuator 70 so that the wedge 40 is pulled out of the tension member 1. By reliably releasing the force to ask, after the construction of the structure at the construction site is made of a structure capable of stable and reliable dismantling of the tension member (1).

The housing 20 is configured by screwing the first housing 24 and the second housing 28. In the first housing 24, an insertion hole 22 into which the tension member 1 enters is formed at one end in the longitudinal direction, and a guide surface 24a narrowing toward the insertion hole 22 is formed therein. In addition, the first housing 24 has a locking end 26 is formed in the base end opposite to the insertion hole 22, the screw portion is formed in the peripheral portion of the base end side of the first housing 24. The second housing 28 is formed in the front space therein to accommodate the wedge 40 and the reverse operation member 60 to be described later. A screw portion is formed on the inner circumferential surface of the front space portion of the second housing 28 so that the housing 20 can be formed by being screwed to the screw portion formed on the proximal end side of the first housing 24. And, the second housing 28 is a cap member 80 is screwed to the end opposite to the front end portion that is screwed with the first housing 24.

The wedge 40 is composed of a plurality of wedge pieces 44 having tapered outer surfaces so as to move along the guide surface 24a of the first housing 24 to be spaced apart or close to each other, and each of the wedge pieces 44 On the inner surface facing the concave-convex portion is formed to increase the fastening force with the surface of the tension member 1, the engaging jaw 42 is formed to engage the engaging jaw 74 formed on the front end of the wedge reverse actuator 70 to be described later do. In addition, the wedge 40 has an elastic coupling ring 43a wound around the proximal end side surface facing the wedge reverse actuator 70 so that a partial coupling force is applied to each wedge piece 44. In addition, the outer circumferential surface of the wedge 40 has a stepped portion 46 protruding from the outer surface adjacent to the portion around which the coupling ring 43a is wound.

The reverse operation member 60 is formed in a ring shape having a hole 68 formed in the center portion thereof while having elasticity, and engaging the stepped portion 46 and the first housing 24 protruding to the outer surface of the wedge 40. It is coupled to the circumference of the wedge 40 so as to be interposed between the stages 26. The reverse actuating member 60 is shaped into a cone, and the reverse actuating operation is performed such that one end of the reverse actuating member 60 faces the step 46 of the circumference of the wedge 40 or the engaging end 26 of the first housing 24. The member 60 is coupled to the circumference of the wedge 40. In the exemplary embodiment of the present invention, one end of the reverse operation member 60 faces the step 46 of the wedge 40, while the other end of the reverse operation member 60 is engaged with the locking end 26 formed in the first housing 24. Coupled to the periphery of the wedge 40.

As described above, the reversing actuating member 60 having the elasticity is the end 26 of the first housing 24 by the stepped portion 46 of the circumference of the wedge 40 when the tensioning force is applied by pulling the tension member 1 by a separate tensioner. Each divided wedge piece of the wedge 40 is held in an unfolded state while retaining elasticity while being pushed in the direction, and then retracted from the wedge 40 again when the tension force acting on the tension member 1 is returned to its original position. Let (44) be in a state where it can happen.

The coil spring 50 is fixed to the housing 20 at the proximal end side of the wedge 40. Specifically, the bolt 82 is provided on the inner end of the cap member 80 coupled to the base end of the second housing 28, the nut 84 is coupled to the bolt 82, the coil spring 50 The key hook portion bent at the proximal end is fitted to the circumference of the bolt 82 and is fixed by the nut 84, whereby the coil spring 50 is fixed to the cap member 80 to form a structure installed in the housing 20. . Specifically, the coil housing 50 is built in the second housing 28.

The wedge reverse actuator 70 is formed in a circular block shape, the spiral groove 72 formed on the circumference is coupled to the coil spring 50 so as to be rotatable and connected to the rear end of the wedge 40 at the same time. do. Preferably, the locking jaw 74 is formed to protrude from the tip end side circumference of the wedge reversing actuator 70, the wedge 40 has a coupling jaw 42 is formed at the proximal end, and is engaged with the locking jaw 74 The engagement engagement of the jaw 42 takes the structure of the wedge retracting actuator 70 and the wedge 40 interconnected.

According to the present invention having such a configuration, the wedge 40 is usually advanced in the direction of the insertion hole 22 of the distal end of the first housing 24 by the force of the coil spring 50, so that each wedge of the wedge 40 is divided. The side of the through hole 68 protruding from one side of the reverse operation member 60 to the other side while the piece 44 is kept in a narrowed state by the narrow guide surface 24a inside the first housing 24 is a wedge. 40 is in contact with the stepped portion 46 and the other side of the reverse operation member 60 is in contact with the engaging end 26 of the first housing 24. That is, the reverse operating member 60 is maintained in a state interposed between the step 46 of the wedge 40 and the locking end 26 of the first housing 24.

In this state, when the tension member 1 is pushed into the housing 20 through the insertion hole 22 of the front end of the housing 20 (that is, the front end of the first housing 24), the wedge 40 and the wedge are retracted. As the actuator 70, the coil spring 50, and the reversing actuating member 60 are pushed back by the tension member 1, the respective wedge pieces 44 of the wedge 40 are separated from each other and the tension member (between each wedge 40) 1) will pass. When the tension member 1 is continuously pushed in, the distal end portion of the tension member 1 which has passed between the wedge pieces 44 of the wedge 40 is brought into a state of being fitted into the tension member accommodation groove 76 of the wedge reverse actuator 70. .

When the tension member 1 passes through each wedge piece 44 of the wedge 40 and is inserted into the tension member receiving groove 76 of the wedge reverse actuator 70, and stops pushing the tension member 1, By the elastic force of the coil spring 50, the wedge reversing actuator 70, the wedge 40, and the reversing actuating member 60 are advanced in the direction of the front end insertion hole 22 of the first housing 24, and then wedge ( Since each divided wedge piece 44 of 40 is moved in contact with the surface of the tension member 1 inserted while moving through the guide surface 24a inside the first housing 24, the wedge 40 and the tension member 1 are fastened. This is done.

In such a state that the wedge 40 and the tension member 1 are fastened, the ground anchor is fixed to the anchor hole by pushing into the anchor hole 21 previously formed in the surrounding ground of the construction site and performing cement grouting. 4A to 4C, reference numeral 2 of FIG. 4A is a cover tube of a synthetic resin material, which allows the tension member 1 to be pulled out even when the cement hole is filled and cured.

After fixing the ground anchor coupled with the tension member 1 to the anchor hole of the construction ground as described above, and then pulling the tension member 1 by a separate tensioner, each divided wedge piece 44 of the wedge 40 Since the press surface 24a of the housing 20 is narrower and tightly pressed against the surface of the tension member 1, the wedge 40 and the tension member 1 are strongly engaged, and at the same time, the reverse operation member 60 ) Is stretched between the stepped portion 46 of the circumference of the wedge 40 and the locking end 26 of the first housing 24 and maintained in elasticity. Thus, the tension member 1 is pulled by the tensioner to obtain a large tension. When connected to a supporting structure (for example, H beam, etc.) under a load, it is possible to firmly support a structure such as an earth wall by the tension member 1 as described above.

On the other hand, after installing the tension member (1) by the ground anchor, and the construction of the building structure, such as underground structures, and the like, and after a certain time after completion of the construction of the building structure, when the tension force applied to the tension member (1) is released, the wedge (40) By retracting the wedge 40 again while the reverse actuating member 60, which was maintained in the unfolded state between the stepped portion 46 of the circumference portion 46 and the locking end 26 of the first housing 24, is restored to its original position again. The wedge 40 is spaced apart from the guide surface 24a of the housing 20.

As such, the wedge 40, which exerts a force to apply the tension member 1, is retracted by the elastically restored reverse operation member 60, and then the tension member 1 is rotated in one direction. Since the wedge 40 is further retracted while rotating backward along the coil spring 50 by the negative spiral groove 72, the wedge 40 is in a state capable of completely releasing the force applied to the tension member 1. That is, since the rear end of the wedge 40 is connected to the front end of the wedge reverse actuator 70, when the tension member 1 is rotated, the wedge reverse actuator 70 is wound by the spiral groove 72 around the coil spring. Since it rotates backward along 50 and at the same time the wedge 40 is also reversed, the wedge 40 is able to release the force that forces the tension member 1. At this time, the tension member receiving groove 76 of the wedge reverse actuator 70 is configured in a polygonal groove shape, the tension member 1 is inserted into the tension member receiving groove 76 of the polygon groove shape, the tension member (1) rotation The tension member accommodating groove 76 of the sea wedge reverse actuator 70 acts as a locking key, so that the tension member 1 is rotated together with the wedge reverse actuator 70 without turning out, so that the tension member 1 It is possible to reliably perform the reverse rotation of the wedge reverse actuator 70 by the rotation and the reverse motion of the wedge 40.

As such, the wedge retracting mechanism 70 further retracts the wedge 40 by the rotational operation of the tension member 1, and pulls the tension member 1 to the outside in a state where the force applied by the tension member 1 is completely released. On the main surface, since the tension member 1 is separated from the inside of the housing 20, the tension member 1 can be easily dismantled.

Therefore, when the tension member dismantled ground anchor of the present invention releases the tension force of the tension member 1, the back surface 24a inside the first housing 24 by reversing the wedge 40 while the reverse operation member 60 is restored to its original state. And then rotate the tension member 1 in one direction so that the wedge reversing actuator 70 is rotated backward along the coil spring 50 by the spiral groove 72 at the periphery to further retract the wedge 40. The wedge 40 is in a state capable of completely releasing the force applied to the tension member (1), and in this state, just by pulling out the tension member (1), the dismantling work of the tension member (1) is easy and quick effect And, since the parts for performing the dismantling operation of the smooth tension member (1) is made of only the coil pring and the wedge reversing actuator 70 and the reversing actuating member 60, the overall structure can be simply implemented, thereby In addition, it can be expected that the product cost can be lowered relatively.

On the other hand, according to the present invention, the inner end of the cap member 80 is provided with a bolt 82, the nut 82 is coupled to the bolt 82, the key hook formed bent at the proximal end of the coil spring (50) Since the coil spring 50 is fixed to the inner end of the cap member 80 by being fitted to the circumference of the additional bolt 82, the nut 84 is loosened or tightened if necessary. There is also an effect to facilitate the assembly and disassembly of the coil spring 50 can be made.

5 is an exploded perspective view of the main part of the second embodiment of the present invention, wherein the tension member receiving groove 76 of the wedge reverse actuator 70 is configured in the shape of a polygonal groove. In the second embodiment of the present invention, the tension member accommodating groove 76 has a hexagonal groove shape, and the tension material 1 is made of six strands of wire twisted about the one strand of the wire. 76 is also made of a hexagonal groove shape.

According to the second embodiment of the present invention, the tension member 1 is inserted into the tension member accommodating groove 76 of the polygonal groove shape, the tension member of the polygon groove shape of the wedge reverse actuator 70 when the tension member 1 rotates. The receiving groove 76 acts as a locking key so that the tension member 1 is rotated together with the wedge reverse actuator 70 without turning, so that the wedge reverse actuator 70 is rotated by the tension member 1. There is an advantage that it is possible to reliably perform the rotation reverse operation. That is, by allowing the tension member 1 to rotate together without turning against the wedge reverse actuator 70, the force applied to the tension member 1 by the reverse of the wedge reverse actuator 70 and the wedge 40 can be seen. Since it can be completely released, the effect of further increasing the reliability during dismantling the tension member (1) is lowered.

On the other hand, Figure 6 is a third embodiment of the present invention, the insertion hole 22 into which the tension member 1 enters in one end of the longitudinal direction is formed and the guide surface (N) narrowed toward the insertion hole 22 direction ( 24a is formed and is provided on the end side opposite to the insertion hole 22, the housing 20 having a locking end 26, and a plurality of tapered outer surfaces of the housing 20 is provided inside the guide surface (24a) The wedge 40 is composed of a wedge piece 44 is moved along the guide surface (24a) of the housing 20, the pressure wedge 40 is in close contact or spaced on the surface of the tension member 1, between the interior of the housing 20 and the wedge 40 A coil spring 50 interposed therebetween to push the wedge 40 toward the guide surface 24a of the housing 20, a stepped portion 46 protruding to the outer surface of the wedge 40, and a locking end of the housing 20 ( The wedge 40 is coupled to the circumference of the wedge 40 so as to be interposed between the housings 20 upon release of the tension force acting on the tension member 1. Consists of the reverse operation member 60 to retract in the direction opposite to the insertion hole 22 of the.

According to the third embodiment of the present invention having such a configuration, the tension member 1 is introduced into the housing 20 through the insertion hole 22 of the front end of the housing 20 (that is, the front end of the first housing 24). When pushed in, the coil spring 50 and the wedge 40 and the reversing actuating member 60 are pushed back by the tension member 1, so that each wedge piece 44 of the wedge 40 is open to each other and between each wedge 40. The tension member 1 passes through.

When the tension member 1 passes through each wedge piece 44 of the wedge and stops pushing the tension member 1, the wedge 40 and the reverse operating member 60 are moved by the elastic force of the coil spring 50. The wedge piece 44 of the wedge 40 is moved forward by moving toward the front end insertion hole 22 of the first housing 24 while being moved on the guide surface 24a inside the first housing 24. The wedge 40 and the tension member 1 are fastened by being in close contact with the surface of the tension member 1, and the tension member 1 is separated by a separate tensioner in the state where the wedge 40 and the tension member 1 are fastened. When pulled out, since each divided wedge piece 44 of the wedge 40 is strongly press-contacted to the surface of the tension member 1, the wedge 40 and the tension member 1 are strongly engaged, and at the same time, the reverse operation member 60 is held between the stepped portion 46 of the circumference of the wedge 40 and the locking end 26 of the first housing 24 while maintaining the elasticity. When connected to a pulling by a tension of material 1 (e.g., H beam, etc.) to the support structure is subjected to a large tensile load state, it is possible to firmly support the structure by a tension member (1).

On the other hand, after the construction of the underground structure, such as after a certain time to release the tensile force applied to the tension member 1, the stepped end 26 of the stepped portion 46 and the first housing 24 of the periphery of the wedge 40 The reverse actuating member 60, which was maintained in the unfolded state, retracts the wedge 40 again while being elastically restored to its original position.

In this state, if the tension member 1 is pushed further momentarily and the tension member 1 is pulled out quickly, the tension member 1 can be quickly removed from the wedge 40, so that the dismantling work of the tension member 1 can be performed quickly and easily. It can be done.

In addition, Figure 7 is a cross-sectional view showing the internal structure of the fourth embodiment of the present invention, the fourth embodiment of the present invention is a structure in which the reverse operating member 60 constituting the first embodiment of the present invention is omitted, When the tension member 1 rotates in one direction, the wedge reversing actuator 70 is rotated backward along the coil spring 50 by the spiral groove 72 around the wedge 40, so that the wedge 40 is further retracted. It becomes a state which can completely release the force which asked the tension material 1, and the wedge reverse actuator 70 further retracts the wedge 40 by the rotation operation of the tension material 1, If the tension member 1 is pulled out after the force is completely released, the tension member 1 can be easily dismantled because the tension member 1 is separated from the inside of the housing 20.

Meanwhile, a tapered portion 42a which is inclined downward from the proximal end of the wedge 40 toward the distal end portion is formed at the engaging jaw 42 formed at the proximal end of each wedge piece 44 of the wedge 40. The engaging jaw 74 of the wedge retracting actuator 70 engaged with the engaging jaw 42 of () is formed with a tapered portion 74a which is inclined upward from the distal end portion to the proximal end portion, thereby the wedge reversing actuator 70. As the reverse operation, the wedge (42a) formed on the engaging jaw 74 of the wedge reversing actuator 70 ascends the tapered portion (42a) formed on the engaging jaw 42 of the wedge 40 Since each wedge piece 44 of 40 is made to spread reliably, there exists an effect which can reliably dismantle the tension material 1 bitten by the wedge 40.

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8 and 9 illustrate a fifth embodiment of the present invention, and according to FIGS. 8 and 9, between the tip of the wedge 40 and the inside of the housing 20 (specifically, the inside of the first housing 24). The reverse operation member 60 is additionally provided, and the wedge 40 is more smoothly reversed by the two reverse operation members 60 than when the reverse operation member 60 is provided. , This also means that the dismantling work of the tension member 1 is made more smoothly. Reference numeral 61 is a washer and has a function of arranging the reverse actuating member 60 at the distal end of the wedge 40 so as not to be separated. Preferably, as in the sixth embodiment of the present invention shown in FIG. 10, by providing two reverse actuating members 60 facing each other so as to be symmetric with each other, a total of three reverse actuating members 60 are provided. ) May cause the wedge 40 to reverse run.

On the other hand, in Figures 8 and 9, but two or more reverse operating member 60 is shown installed, the reverse operating member 60 is coupled to the circumference of the wedge 40, the step 46 of the wedge 40 ) And the reverse actuating member 60 may be provided only between the locking end 26 of the housing 20, and the reverse actuating member 60 may be provided only between the front end of the wedge 40 and the inner space of the housing 20. May be provided at the same time between the step 46 of the wedge 40 and the locking end 26 of the housing 20, and between the front end of the wedge 40 and the space portion of the interior of the housing 20 at the same time Note that the operating member 60 may be provided.

11 and 12 illustrate a seventh embodiment of the present invention, in which a triangular protrusion 64 is formed on an inner circumferential surface of the reverse operation member 60 to form a wedge 40 together with the wedge reverse actuator 70. As the reverse operation, the triangular protrusion 64 of the reverse operation member 60 is interposed between the respective wedge pieces 44 of the wedge 40, so that each wedge piece 44 is uniformly opened, When dismantling the tension member 1, an effect such as easier can be expected.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various permutations, modifications, and changes can be made without departing from the spirit of the present invention. It will be apparent to those who have it.

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

Figure 2 is a perspective view showing a state in which the wedge and the reverse operating member shown in FIG.

Figure 3 is a perspective view showing a state in which the wedge reverse actuator and the coil spring and the cap member shown in FIG.

4a to 4e are cross-sectional views showing the internal structure and operating state of the present invention

5 is an exploded perspective view showing a second embodiment of the present invention.

6 is a cross-sectional view showing the internal structure of a third embodiment of the present invention.

7 is a cross-sectional view showing the internal structure of a fourth embodiment of the present invention.

8 is a perspective view showing the main parts of a fifth embodiment of the present invention;

9 is a cross-sectional view showing the internal structure of FIG.

10 is a cross-sectional view showing a sixth embodiment of the present invention.

11 is a perspective view showing the main parts of a seventh embodiment of the present invention;

12 is a cross-sectional view showing the internal structure of FIG.

Claims (9)

An insertion hole 22 into which the tension member 1 enters at one end of the longitudinal direction, and a housing 20 having a guide surface 24a narrowing toward the insertion hole 22 in the longitudinal direction, and the housing 20. Wedges provided inside the guide surface 24a of the plurality of wedge pieces 44 whose outer surfaces are formed to be tapered and moved along the guide surface 24a of the housing 20 while being press-contacted or spaced from the surface of the tension member 1. 40 and a reverse actuating member 60 which is embedded in the housing 20 and retracts the wedge 40 when the tension force acting on the tension member 1 is released, and at the proximal end side of the wedge 40. The coil spring 50 installed in the housing 20 and the spiral groove 72 formed at the circumference thereof are rotatably coupled to the coil spring 50 and connected to the rear end of the wedge 40 and the tension member. At the distal end facing the end of (1), the tension member receiving groove (76) It is configured to include a wedge reverse actuator 70 is formed, The tension member accommodating groove 76 of the wedge reverse actuator 70 has a polygonal groove shape, and the tension member 1 is inserted into the tension member accommodating groove 76 of the polygon groove shape. Type ground anchors. According to claim 1, wherein the reverse operation member 60 is formed in a cone shape at the same time as a ring shape with a through hole 68 formed on the inner circumferential surface, one end of the reverse operation member 60 is formed around the wedge 40 A retractable ground anchor, characterized in that the reverse actuating member (60) is coupled to the circumference of the wedge (40) to face the step (46) or the locking end (26) of the first housing (24). According to claim 1, wherein the wedge reverse actuator 70 is formed with a locking projection (74) protruding on the front end portion side, the wedge 40 is coupled to the proximal end facing the wedge reverse actuator (70) The jaw 42 is formed, and the wedge retracting mechanism 70 and the wedge 40 are connected to each other by engaging the engaging jaw 74 and the engaging jaw 42. Type ground anchors. According to claim 3, The housing 20 has an insertion hole 22 is formed in the front end, the guide surface 24a is formed on the inner peripheral surface and the first housing 24 formed with a threaded portion on the proximal end side portion and the front inside The second housing 28 is formed with a space for accommodating the wedge 40 and the reverse operation member 60 and a threaded portion formed on the inner circumferential surface of the space to be screwed to the threaded portion of the first housing 24. It is configured to include, the second housing 28 is a cap member 80 is screwed to the end opposite to the front end portion is coupled to the first housing 24, the inner side of the cap member 80 The end of the tension member disassembly type ground anchor, characterized in that the coil spring (50) is fixed. According to claim 1, wherein the tension member receiving groove (76) of the wedge reverse actuator 70 is configured in a polygonal groove shape, the tension member 1 is inserted into the polygonal material receiving groove 76 of the polygonal groove shape. Tension member dismantling ground anchors, characterized in that. According to claim 1, A plurality of protrusions 64 is formed on the inner circumferential surface of the through hole 68 of the reverse operation member 60, the wedge 40 together with the wedge reverse actuator 70 is reversely operated as the A tension member dismantling type ground anchor, characterized in that the wedge portion 64 of the reverse operation member 60 is sandwiched between the wedge pieces 44 of the wedge 40 so that each wedge piece 44 is evenly spread. . The wedge (40) of claim 1, wherein the reverse operation member (60) is interposed between the stepped portion (46) protruding to the outer surface of the wedge (40) and the locking end (26) formed inside the housing (20). Is coupled between the periphery of the wedge 40 or between the front end of the wedge 40 and the inner space of the housing 20, so as to release the tension force acting on the tension member 1, A tension member dismantling ground anchor, characterized in that the wedge (40) is operated backward. delete delete

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