KR200403703Y1 - Exclusion type ground anchor body structure - Google Patents

Abstract

The present invention is excellent in workability because the rotor blades formed in the wedge and the wedge cap move up and down along the space between the spring and the spring by the rotational force, and the wedge can be restrained and released from the block to easily and easily remove and recombine the strands. Since the spring is coupled to the spring key groove of the rotary blade to maintain the elastic force, and the anchor body completely supports the wedge when transporting and moving or inserting the anchor body into the perforation, the removable ground anchor structure that can be perfect construction .

It has a predetermined space (11) inside the block 10 having a threaded hole (12) on the inner surface of the upper end and the insertion hole 13 is inserted into the strand (90) at the bottom; A wedge 20 installed in the inner space 11 and forming a coupling groove 21 on an upper inner surface, a rotary blade 22 on an upper surface thereof, and a spring key groove 23 on an upper surface thereof; The wedge cap 30 is coupled to the coupling groove 21 and forms a plurality of fixing protrusions 32 on the top of the hollow 31 formed therein and a rotating plate 34 having a plurality of wings 33 formed at the bottom thereof. ; The block 10 is screwed to the upper end of the block 10, the thread 41 is formed on the lower outer surface and the block cap 40 having a spring 50 formed with a fixing pin 51 bent end therein.

Description

Removal type ground anchor body structure

The present invention relates to a structure of a removable ground anchor, and more particularly, the rotor blade formed on the wedge and the wedge cap moves up and down along the space between the springs to constrain and release the wedge from the block, thus making the strand very simple and easy. Can be separated and recombined.

In general, the ground anchor is formed by drilling an anchor hole in the ground and inserting a tensile material (strand wire) having excellent tensile strength into the anchor hole together with an internal fixing agent and a load bearing body, and then injecting it into a grouting material such as concrete to fix it firmly. Next, by applying a load to the free end of the tension member and fixing it with an external fixing agent to secure a strong fixing force to secure structures such as earth walls, and to prevent the collapse of the surrounding ground during excavation work for underground structures in construction and civil engineering works. It is widely used for earthquake construction and construction to control the loss of soil on the soft ground incision surface.

The tensile material used for the ground anchor uses a strand made of twisted steel strands, which is stronger than ordinary reinforcing bars, and becomes a ground obstacle when left in the ground. There is a risk of causing problems. In order to solve this problem, there has been known an internal fixing agent for a removable ground anchor that easily removes a tension member buried in the ground after construction work.

However, the conventional internal fixing agent for removable ground anchors can easily remove the tension member in the event of impact on the internal fixing unit of the anchor during the process of transporting the anchor manufactured at the factory to the construction site or during the construction work. There was a problem that could not be.

In addition, there is a problem that occurs before the tension, that is, when the tensile material is short or the tensile material is incorrectly coupled, there is a problem that takes a lot of time and additional costs because there is no way to remove the tensile material and recombine again.

The present invention has been made in consideration of various problems as described above. The purpose of the wedge and the wedge cap is to rotate and restrain the wedge in the block while moving up and down along the space between the spring and the spring by the rotational force of the strand It is possible to remove and recombine the strands easily and easily to provide a removable ground anchor structure with excellent workability.

Hereinafter, described in detail by the accompanying drawings a preferred embodiment of the present invention as follows.

1 is a view showing the overall configuration of the present invention, the reference numeral 100 of the drawing shows the main body of the ground anchor body of the present invention.

The main body 100 has a predetermined space 11 therein, the block 10 to which the strands 90 are coupled to the lower side, and is installed in the internal space 11 of the block 10 and the coupling groove 21 therein. ) And a rotor blade 22 is formed on the outer circumferential surface and the wedge 20 having the spring key groove 23 on the upper surface thereof, and the fixing protrusion 32 is formed on the upper end of the hollow 31, and the wings 33 are formed on the lower end thereof. It consists of a wedge cap 30 having a rotating plate 34 and a block cap 40 is provided with a screw thread 41 is formed on the lower outer peripheral surface and a spring 50 formed with a fixing pin 51 at the lower end.

The block 10 forms a constant space 11 therein, which has an upper space 11a having a vertical shape, and a lower space 11b having a sloped surface for inserting the wedge 20. They are connected to each other.

A thread 12 is formed on the inner circumferential surface of the end of the upper space 11a of the block 10, and an insertion hole 13 into which the strand wire 90 is inserted is formed at the lower end thereof.

The strand 90 is formed by twisting the strands of one strand in the center and the strands of 6 strands on the outer surface and wrapping the outer surface with a covering tube. And the front end is cut off the covering tube, and then inserted into the insertion hole 13 of the block 10 and used to fasten it with the wedge 20.

The wedge 20 is installed in the lower space (11b) of the block 10, as shown in the accompanying drawings Figure 2 is equally divided into three sides and forming a coupling groove (21) in each upper upper surface The upper middle portion forms a rotary blade 22 protruding forward, and the spring key groove 23 is formed on the upper surface.

Since the position of the spring key groove 23 is formed in the inner side smaller than the diameter of the spring 50 to be described later distance from the center has a property to be unfolded by the elastic force of the spring (50).

Then, the wedge 20 has a three-sided fastening ring 25 to the groove 24 formed on the upper outer circumferential surface so that the three sides are connected to each other.

The wedge cap 30 is formed in a cylindrical shape and a hollow 31 is formed therein, and forms six fixing protrusions 32 on the inner circumferential surface of the upper end of the hollow 31. As shown in FIG. 3, the fixing protrusion 32 is formed in a circular shape in which the strand 90 can enter the outer circumferential groove 91 formed when six strands are twisted.

The fixing protrusion 32 serves to allow the strand wire 90 to be coupled to the outer circumferential groove 91 to be simultaneously rotated with the wedge cap 30 when the strand wire 90 rotates.

And at its lower end is formed a circular rotary plate 34 extended than the hollow, and on the outer surface to form a wing 33 is divided evenly three at a constant angle.

The rotating plate 34 of the wedge cap 30 is inserted into the coupling groove 11 of the wedge 20, and the wings 33 transmit the rotational force to the wedge 20.

The block cap 40 forms a thread 41 coupled to the thread 12 formed on the upper inner surface of the block 10 on the lower outer surface. And there is installed a spring 50 having a fixing pin 51, the end of which is bent downward.

The fixing pin 51 of the spring 50 is installed in the spring key groove 61 formed in the rotary blade 60 of the wedge 20. At this time, the inner surface of the spring 50 is in a state that the wedge cap 30 is entered.

When the block cap 40 is coupled to the block 10, it is installed after the rubber ring 60 is coupled to block the inflow of moisture or foreign substances into the block 10.

Referring to the operating state of the present invention as described above are as follows.

First, as shown in FIG. 4A, the wedge 20 used to fix the strand 90 to the inner space of the block 10 is in an initial assembly state due to the elastic force of the opening ring 25 fastened to the outer surface. Instead of being completely stuck in the lower space 11b of the block 10, it is raised slightly upward.

At this time, the spring 50 is installed in the wedge 20 is pressed by the wedge 20 by the elastic force, the spring keyway groove of the rotary blade 23 to prevent the spring 50 and the wedge 20 is united to move ( 23) is fixed to the fixing pin 51 bent to the bottom of the spring (50).

Such an assembly state is to prevent the strand wire 90 from falling out when the wedge 20 moves in the internal space of the block 10 when carrying the anchor body or moving the anchor body and inserting the anchor body into the ground.

In this state, when the tension wire 90 is tensioned as shown in FIG. 4B, the wedge 20 moves downward by the tension force and is completely inserted into the lower space 11b of the block 10. The fixing pin 51 of the spring 50, which has been inserted into the spring key groove 23 of the rotary blade 22, is separated and is in a loose state.

At this time, after removing the long tensile force applied to the stranded wire 90 as shown in Figure 4c accompanying the clockwise turning the stranded wire 90, the rotation force is the wedge 20 and the wedge cap fastened to the wedge 20 ( 30) is delivered.

At this time, the rotary blade 22 protruding forward on the upper end of each wedge 20 is inserted into the space between the spring 50 and the spring 50 to ride up the interspace, the wedge 20 is It is separated from the lower space 11b of the block 10 and loses the restraining force.

At this time, the wedge 20 is pulled out by the opening ring 25 fastened to the outer circumferential surface as much as the free space while exiting the lower space (11b).

In this state, as shown in FIG. 4D, when the strand 90 is pulled downward, the strand 90 is pulled out and the wedge 20 detached from the lower space 11b of the block 10 is a rotary blade 22. ) Is kept in a state of being fitted in the space between the spring 50 and the spring (50).

As such, the rotary blade 22 of the wedge 20 is caught in the space between the springs 50 and only the strand 90 falls outward.

When recombination of the strands 90 in the above state, that is, when the strands are short or there is a problem before the tension is required to replace the strands, or when the re-tension is necessary after removing the strands as shown in the accompanying drawings, Figure 4e As described above, the stranded wire 90 is inserted into the block 10. Then, the tip of the strand 90 passes through the wedge 20 and is coupled to the hollow 31 of the wedge cap 30. At this time, the fixing protrusion 32 provided on the inner surface of the hollow 31 is inserted into the outer circumferential surface groove 91 of the strand wire (90).

In this state, as shown in FIG. 4F, when the twisted wire 90 is rotated counterclockwise, rotational force is transmitted to the wedge 20 and the wedge cap 30.

At this time, the rotary blade 22 coupled to the wedge 20 descends downward through the space between the spring 50 and the spring 50 so that the wedge 20 is again in the lower space 11b of the block 10. It will be fully inserted and bound.

In addition, another embodiment of the present invention will be described in detail with reference to the accompanying drawings.

5, the main body 100 of the present invention has a predetermined space 11 therein and a block 10 to which the strands 90 are coupled to the lower side, and an internal space of the block 10 ( 11) and the wedge 20 having a coupling groove 21 therein, and a fixing projection 32 at the top of the hollow 31, the rotary blade 37 having a spring key groove 38 on the upper surface at the bottom. It consists of a wedge cap 30 having a rotating plate 34 is formed, and the block cap 40 is provided with a screw thread 41 is formed on the lower outer peripheral surface and the spring 50 is formed with a fixing pin 51 at the lower end.

The block 10 forms a constant space 11 therein, which has an upper space 11a having a vertical shape, and a lower space 11b having a sloped surface for inserting the wedge 20. They are connected to each other.

A thread 12 is formed on the inner circumferential surface of the end of the upper space 11a of the block 10, and an insertion hole 13 into which the strand wire 90 is inserted is formed at the lower end thereof.

The strand 90 is formed by twisting the strands of one strand in the center and the strands of 6 strands on the outer surface and wrapping the outer surface with a covering tube. And the front end is cut off the covering tube, and then inserted into the insertion hole 13 of the block 10 and used to fasten it with the wedge 20.

The wedge 20 is installed in the lower space 11b of the block 10, is equally divided into three sides, and the coupling groove 21 is formed on the upper inner surface of each side.

Then, the wedge 20 has a three-sided fastening ring 25 to the groove 24 formed on the upper outer circumferential surface so that the three sides are connected to each other.

The wedge cap 30 is formed in a cylindrical shape and a hollow 31 is formed therein, and six fixing protrusions 32 are formed on the inner circumferential surface of the upper end of the hollow 31. The fixing projection 32 is formed in a circular shape that can enter the outer circumferential groove 91 formed when the strand 90 is twisted six strands.

And the lower end of the hollow 31 to form a rotary blade 37 is divided into three and to form a spring key groove 38 on one side of the upper surface. And between the rotary blades 37 to form a rotary plate 34 narrower than the rotary blade 37.

The rotating plate 34 is installed in the coupling groove 21 of the wedge 20, the rotary blade 37 is maintained to protrude to the outside.

In addition, since the position of the spring key groove 38 is formed inside the distance smaller than the diameter of the spring 50 to be described later from the center has a property to be unfolded by the elastic force of the spring 50.

The block cap 40 forms a thread 41 coupled to the thread 12 formed on the top of the block 10 on the lower outer surface. And there is installed a spring 50 having a fixing pin 51 is bent to the lower end in the interior, the fixing pin 51 of the spring 50 is a spring key groove formed on the rotary blade 37 of the wedge cap 30 It is installed in 38.

When the block cap 40 is coupled to the block 10, it is installed after the rubber ring 60 is coupled to block the inflow of moisture or foreign substances into the block 10.

Referring to the operating state of the present invention as described above,

First, as shown in FIG. 6A, the wedge 20 to which the strand 90 is fastened is the lower space 11b of the block 10 in the initial assembly state by the elastic force of the open ring 25 fastened to the outer surface. It is not completely stuck in, but is slightly raised upwards.

At this time, the spring 50 installed in the wedge cap 30 is pressed by the wedge cap 30 by the elastic force, the spring 50 and the spring 50 by the spring key groove 38 to prevent the spring 50 and the wedge 20 to be integrated. Insert the fixing pin 51 bent at the bottom of the fixed).

Such an assembly state is to prevent the wedge 20 from moving inside the block 10 when the anchor body is transported or moved in the field and the anchor body is inserted into the ground, thereby preventing the strand wire 90 from falling out.

In this state, when the tension wire 90 is tensioned as shown in FIG. 6B, the wedge 20 moves downward by the tension force and is completely inserted into the lower space 11b of the block 10. The fixing pin 51 of the spring 50, which is inserted into the upper surface spring key groove 38 of the rotary blade 37 of the wedge cap 30, is separated and is in a loose state.

At this time, after removing the long tensile force applied to the stranded wire 90 as shown in Figure 6c attached to the clockwise rotation of the stranded wire 90 by the rotational force the wedge cap 30 in the same direction and at the same time forward The protruding rotary blade 37 is inserted into the space between the spring 50 and the spring 50 to rise up through the interspace, and the wedge 20 is lowered from the lower space 11b of the block 10. You will be released and you will lose your binding force.

At this time, the wedge 20 is pulled out by the opening ring 25 fastened to the outer circumferential surface as much as the free space while exiting the lower space (11b).

In this state, as shown in FIG. 6D, when the stranded wire 90 is pulled downward, the stranded wire 90 is pulled out and at the same time, the wedge 20 is separated from the lower space 11b of the block 10 and the wedge cap 30 The rotary blade 37 of) is maintained in a state fitted in the space between the spring 50 and the spring (50).

As such, the rotor blade 37 of the wedge cap 30 is caught in the space between the springs 50 and only the strand 90 falls outward.

When the stranded wire 90 is to be rebound in the above state, that is, when the stranded wire is short or there is a problem before tension, and when the stranded wire needs to be replaced, or when the stranded wire is required to be re-tensioned after removing the stranded wire from FIG. As shown, the strand 90 is inserted into the block 10. Then, the tip of the strand 90 passes through the wedge 20 and is coupled to the hollow 31 of the wedge cap 30. At this time, the fixing protrusion 32 provided on the inner surface of the hollow 31 is inserted into the outer circumferential surface groove 91 of the strand wire (90).

In such a state, when the strand wire 90 is turned counterclockwise, the rotational force is transmitted to the wedge cap 30, and at this time, the rotation blade 70 formed on the wedge cap 30 is a spring 50 and a spring 50. Ride down the space between the wedge 20 is completely inserted back into the lower space (11b) of the block 10 will have a binding force.

As described in detail above, the present invention can be easily and easily removed and recombined the stranded wire by constraining and releasing the wedge from the block while the rotary blades formed on the wedge and the wedge cap move up and down along the space between the spring and the spring by the rotational force. There is an excellent workability.

In addition, the present invention is the spring is coupled to the spring key groove of the rotary blade to maintain the elastic force, the anchor body prevents the wedge from moving in the block during transport and movement or when inserting the anchor body in the perforation can be perfect construction There is this.

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

2 is a cross-sectional view showing a wedge configuration of the present invention

3 is a cross-sectional view showing the configuration of the wedge cap of the present invention

4a to 4f is a cross-sectional view showing an operating state of the present invention

5 is an exploded perspective view showing another configuration of the present invention

6a to 6e is a cross-sectional view showing an operating state of another configuration of the present invention

<Explanation of symbols for main parts of the drawings>

100: body 10: block

11: space 12, 41: thread

20: wedge 21: coupling groove

22,37: rotor blade 23,38: spring keyway

30: wedge cap 31: hollow

32: fixing protrusion 33; wing

34: rotating plate 40: block cap

50: spring 51: holding pin

Claims (2)

A block 10 having a predetermined space 11 therein and having a thread 12 formed at an upper inner surface thereof and an insertion hole 13 inserted at a lower end line 90 thereof; A wedge 20 installed in the inner space 11 and forming a coupling groove 21 on an upper inner surface, a rotary blade 22 on an upper surface thereof, and a spring key groove 23 on an upper surface thereof; The wedge cap 30 is coupled to the coupling groove 21 and forms a plurality of fixing protrusions 32 on the top of the hollow 31 formed therein and a rotating plate 34 having a plurality of wings 33 formed at the bottom thereof. ; The block 10 is screwed to the top of the block 10, the thread 41 is formed on the lower outer surface and a block cap 40 having a spring 50 formed with a fixing pin 51 bent end therein; Removable ground anchor structure. A block 10 having a predetermined space 11 therein and having a thread 12 formed at an upper inner surface thereof and an insertion hole 13 inserted at a lower end line 90 thereof; A wedge 20 installed in the inner space 11 and having a coupling groove 21 formed on an upper inner surface thereof; Rotating plate coupled to the coupling groove 21 and formed a plurality of fixing projections 32 on the top of the hollow 31 formed therein and a plurality of rotary blades 37 having a spring key groove 38 on the upper surface ( A wedge cap 30 having 34); The block 10 is screwed to the top of the block 10, the thread 41 is formed on the lower outer surface and a block cap 40 having a spring 50 formed with a fixing pin 51 bent end therein; Removable ground anchor structure.