KR101765683B1 - Two fracture type anchor assembly of and construction method using the same - Google Patents

Abstract

The present invention relates to a two fracture type anchor assembly and a two fracture type anchor construction method capable of absorbing vibration of an earthquake using the same and, more specifically, relates to a two fracture type anchor assembly and a two fracture type anchor construction method capable of absorbing vibration of an earthquake using the same, wherein the two fracture type anchor assembly is provided with each angle adjustment head capable of adjusting an installation angle of a PC strand in a front end and a rear end of the PC strand, and can absorb vibration in case of an earthquake or large-scale ground deformation. Moreover, in tension, large-scale ground deformation, or an earthquake, a twisting phenomenon of the PC strand is prevented for the PC strand to display the maximum tensile force as force axial lines are the same in any condition. A corrugated pipe is installed for a mounting section to improve a mounting, waterproofing, or frictional force between the PC strand and the ground.

Description

TECHNICAL FIELD [0001] The present invention relates to an anchor assembly for a bony anchor, and a bony anchor assembly method capable of absorbing vibration of an earthquake using the anchor assembly.

The present invention relates to a bony anchor assembly and a bony anchor construction method capable of absorbing vibration of an earthquake using the bony blanket anchor assembly. More particularly, the present invention relates to an angle bending head It is possible to absorb the vibration during earthquake or large scale ground deformation, and to prevent the tilting of the PC strand during the earthquake or the earthquake. And an improvement of frictional force between the PC strand and the ground by installing as many corrugated pipes as the settlement section, and a bony anchor construction method capable of absorbing vibration of the earthquake using the bony anchor assembly .

A general anchor method is used as an anchor force corresponding to an external force such as earth pressure, water pressure, and seismic force generated in construction or is used for stress reinforcement of a structure. It is mainly used for slope reinforcement, retaining wall, excavation surface anchor, Pressure anchor, etc. Nowadays, it is used in high tower and bridge foundation where over-load acts due to the development of anchor design and construction technology, and it is applied in all fields such as plant, dam, and tunnel.

The anchor method is to stabilize the structure by inserting the sheath and the reinforcement into the perforated hole of the grounding machine, injecting the grout material to make the anchor body, and then hardening the anchor body and tensioning the reinforcement material in the anchor head.

In this anchor method, the angle of perforation with the slope for the maximum tension is set so that the angle between the horizon and the stiffener is about 20 ~ 30 경, and the stiffener plate is sloped, and the stiffener is fixed to the head by a wedge When the anchor is pulled, the angle of the hole and the stiffener do not form a straight line, so that the stiffener tends to bend when the tension or large earthquake or earthquake occurs, and the concrete that is applied to the stiffener is damaged.

And reinforcing materials such as steel rods, reinforcing bars, etc., which are formed on the surface at regular intervals or at intervals, are used. However, when such steel bars, reinforcing bars, etc. are obliquely fixed at the fixing portion, or are not straight, there is a fear that localized deflection occurs in the steel bars and reinforcing bars, resulting in stress corrosion and delayed fracture, . Also, it is heavy and not flexible, so that the workability and workability are not good, and it is expensive and not economical.

In addition, the stiffeners inserted in the perforations should be spaced at regular intervals from the excavation surface so that the grout material can be filled tightly between the perimeter and the perforations and the stiffeners are completely covered by the grout. Conventionally, separate spacers have been installed on the steel at regular intervals for this purpose, which is disadvantageous in that it is very troublesome.

Thus, Korean Patent Publication No. 10-1502125 discloses a permanent anchor body using a plurality of PC strands and a method of reinforcing the ground using the same, which can suppress the expected ground displacement after construction or construction.

However, such a patent suffers from difficulty in tensioning the strand. That is, the force that pushes down the plate plate and the force that pulls the strand in the opposite direction are placed in a straight line, which is the most stable structure. If the plate is placed at an oblique angle instead of a straight line, the load applied to a plurality of strands Is not uniform, and it is possible that not only the strand and other parts are damaged due to the ground deformation or breakage of the strand when the earthquake occurs, but also there is a possibility that the pull resistance to be received by the anchor body may weaken.

In order to solve the above problems, the present invention prevents the breakage of PC stranded wire even at large ground deformation, earthquake, or irregular slope, so that it can always exhibit the maximum tensile force and absorbs vibration caused by earthquake As the tensile force of the PC strand is applied, the wedge-shaped inner lower body becomes more rigid as the wedge-shaped inner lower body is integrated and the compressive force and frictional force of the ground are increased. As a result, the ground becomes unstable or the soft ground is effectively It is possible to improve the settlement, waterproofing and frictional force between the PC strand and the ground by installing corrugated pipes as much as the settlement section, and it is possible to use the anchor assembly of the bony type to be able to absorb the vibration of the earthquake using the same. And the like.

A bony anchor assembly according to the present invention includes a plurality of PC strands (10) arranged in a perforation hole of a ground by arranging grout reinjecting pipes (11) for injecting a grout material;

A head member (20) closely attached to the ground and having a distal end portion of the PC stranded wire (10) threadably engaged therewith;

A corrugated pipe (30) surrounding the PC stranded wire and the grout reinforcement pipe in a non-covered state in the fixing section of the perforation hole;

An inner lower body connecting member 40 installed at the rear side of the corrugated pipe 30 and having a rear end of a PC stranded wire inserted therein through an angle adjustable manner;

A wedge-shaped protrusion 500 which is provided at the rear side of the inner lower body connecting member 40 and has an inner hollow shape so that the nail 55 can penetrate through the inner protrusion 500, And a wedge-shaped inner lower body 50 having a plurality of wedge-shaped vanes 510 radially formed thereon.

Also, the bony anchor construction method capable of absorbing the vibration of the earthquake using the bony anchor assembly includes a perforation hole forming step for perforating the perforation hole (A) on the ground for installing the anchor assembly;

An anchor assembly inserting step of inserting a PC stranded wire, a grout reinfusion tube, a corrugated pipe, an inner bottom body connecting member, an inner bottom body, and a nail assembly into the perforation hole A;

Filling the grout material with the grout material by filling the grout material with the grout material injection tube assembled into the assembly;

Filling the grout material into the perforation hole (A), filling the grout material into the perforation hole (A), filling the grout material inside the perforation hole (A);

After removing the grout re-injection tube for external injection, a pressure plate is installed on the ground of the inlet of the perforation hole (A), and the first angle adjusting head is inserted into the hemispherical groove of the extension ring formed on the pressure plate, A step of installing a pressure plate installed on the pressure plate so that the installation angle of the front end of the PC strand is passed through the PC stranded wire;

Adjusting the angle of the first angle adjusting head to adjust the angle of the first angle adjusting head so that the PC stranded wire passing through each fixing hole of the first angle adjusting head is in line with the hole angle of the hole;

A wedge mounting step of mounting a wedge at the tip of each PC stranded wire and installing the fixed wedge of the first angle adjusting head;

A PC strand tensioning step of rotating the wedge to tension each PC strand;

And a head protection cap attaching step of fastening the head protection cap to the thread of the extension ring so as to cover the extension ring.

In the present invention, since the angle adjusting head is installed at the front end and the rear end of the PC stranded wire respectively, it is unnecessary to install the light pressure plate and the concrete for installing the pressure plate in order to adjust the angle of perforation at the slope face, Also, it is possible to maintain a straight line without bending by the angle adjusting head, so that it can exhibit the maximum tensile force and can prevent the breakage of the PC strand and prevent the connected parts from being damaged.

In addition, there is an effect that vibration and vibration during the earthquake can be absorbed by the angle-adjusting head, thereby maintaining the fastening force and the installed state of the assemblies.

The wedge type inner bottom body increases the stiffness of the inner lower body as the pulling force is applied by the action of the PC strand and enhances the compressive force and friction force with the ground while the corrugated tube and the wedge type inner lower body are installed and effectively reinforces the unstable ground or soft ground There is an effect that can support.

1 is a perspective view of a bony anchor assembly according to the present invention;
2 is a sectional view of a bony anchor assembly according to the present invention;
3 is a detailed view of a grout reinforcement tube of a bony anchor assembly according to the present invention.
4 is a detailed view of a head member of a bony anchor assembly according to the present invention;
5 is a detailed view of an inner lower body connecting member of a bony anchor assembly according to the present invention.
6 is a view showing a construction state of a bony anchor assembly according to the present invention.
7 is a view showing a construction process of a bony anchor assembly according to the present invention.

A bony anchor assembly according to the present invention includes a plurality of PC strands (10) arranged in a perforation hole of a ground by arranging grout reinjecting pipes (11) for injecting a grout material;

A head member (20) closely attached to the ground and having a distal end portion of the PC stranded wire (10) threadably engaged therewith;

A corrugated pipe (30) surrounding the PC stranded wire and the grout reinforcement pipe in a non-covered state in the fixing section of the perforation hole;

An inner lower body connecting member 40 installed at the rear side of the corrugated pipe 30 and having a rear end of a PC stranded wire inserted therein through an angle adjustable manner;

A wedge-shaped protrusion 500 which is provided at the rear side of the inner lower body connecting member 40 and has an inner hollow shape so that the nail 55 can penetrate through the inner protrusion 500, And a wedge-shaped inner lower body 50 having a plurality of wedge-shaped vanes 510 radially formed thereon.

Also, the bony anchor construction method capable of absorbing the vibration of the earthquake using the bony anchor assembly includes a perforation hole forming step for perforating the perforation hole (A) on the ground for installing the anchor assembly;

An anchor assembly inserting step of inserting a PC stranded wire, a grout reinfusion tube, a corrugated pipe, an inner bottom body connecting member, an inner bottom body, and a nail assembly into the perforation hole A;

Filling the grout material with the grout material by filling the grout material with the grout material injection tube assembled into the assembly;

Filling the grout material into the perforation hole (A), filling the grout material into the perforation hole (A), filling the grout material inside the perforation hole (A);

After removing the grout re-injection tube for external injection, a pressure plate is installed on the ground of the inlet of the perforation hole (A), and the first angle adjusting head is inserted into the hemispherical groove of the extension ring formed on the pressure plate, A step of installing a pressure plate installed on the pressure plate so that the installation angle of the front end of the PC strand is passed through the PC stranded wire;

Adjusting the angle of the first angle adjusting head to adjust the angle of the first angle adjusting head so that the PC stranded wire passing through each fixing hole of the first angle adjusting head is in line with the hole angle of the hole;

A wedge mounting step of mounting a wedge at the tip of each PC stranded wire and installing the fixed wedge of the first angle adjusting head;

A PC strand tensioning step of rotating the wedge to tension each PC strand;

And a head protection cap attaching step of fastening the head protection cap to the thread of the extension ring so as to cover the extension ring.

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

FIG. 1 is a perspective view of a bony anchor assembly according to the present invention, FIG. 2 is a sectional view of a bony anchor assembly according to the present invention, FIG. 3 is a detailed view of a grout reinforcement tube of a bony anchor assembly according to the present invention, FIG. 4 is a detailed view of a head member of a bony anchor assembly according to the present invention, FIG. 5 is a detailed view of an inner lower body connecting member of a bony anchor assembly according to the present invention, FIG. 7 is a view showing a construction process of a bony anchor assembly according to the present invention. FIG.

The present invention comprises a PC strand 10, a head member 20, a corrugated pipe 30, an inner bottom body connecting member 40 and an inner bottom body 50, as shown in Figs. 1 and 2.

More specifically, a plurality of the PC stranded wires 10 are installed in the perforation holes formed in the ground, and the portion located between the fusing holes in the perforation hole is in a spirally uncovered state because the corrugated pipe 30, which will be described later, The part located between the free gears is installed in a covered state to prevent corrosion.

However, the PC strand 10 is in a spiral state in which the portion located between the fixing devices is not covered, and the rear end portion, which is fastened to the inner bottom body connecting member 40 to be described later, is installed in a covered state.

The PC strand 10 is provided with a corrugated pipe 30 outside the part of the spirally uncoated state where the PC strand 10 in a spiral state is firmly connected to the grouting material in the corrugated pipe 30, Grout reinjecting pipes 11 for grout injection are arranged side by side so as to be improved.

As shown in FIG. 3, the grout re-injection pipe 11 is provided with a grout re-injection pipe (not shown) for inserting a check pin 115 for confirming the installation length of the PC stranded wires 10 installed in the perforation hole A The check hose 110 having a diameter smaller than the inner diameter of the check hose 110 is inserted into the grout re-injection pipe 11 and the check hose 110 is inserted into the grout re- The check hose cover 112 is installed at the tip of the check hose 110 to prevent the grout material from being injected into the check hose 110 and the check hose cover 112 is removed from the check hose 110 as shown in FIG. And the check hose cover 112 is installed on the check hose 110 as shown in FIG. 3B when the grout material is injected.

The check pin 115 is a thin wire and inserted into the check hose 110 to check the installation length of the PC strand 10 through the length of the check pin 115 inserted, To prevent the case.

As shown in FIG. 4, the head member 20 is disposed closely to the entrance side of the perforation hole, and a plurality of PC stranded wires 10 are fastened to each other to provide a tensile force to the PC stranded wire 10, A first angle adjusting head 23, and a head protection cap 24 so as to promptly respond to the bending phenomenon of the PC stranded wire at the time of an earthquake.

The support plate 21 is formed with an extension ring 22 having a predetermined length in the front side so as to allow the tip ends of a plurality of PC strands 10 installed in the perforation hole to pass therethrough, And an outer periphery of the extension ring 22 is formed with a thread 222 of a corresponding shape for engaging with a thread formed on the inner periphery of the head protection cap 24 And the threads 220 formed in the extension ring 22 can be used to remove the head protection cap 24 during reinforcement of the anchor assembly as well as upon engagement of the head protection cap 24, It may be possible to perform reintroduction by being coupled to the terminal 220.

The first angle adjusting head 23 is provided with a plurality of fixing holes 24 so as to fasten the front ends of the PC strands 10 through which the plurality of PC strands 10 passed through the padding 21 pass, And a plurality of fixing holes 230 are formed in a shape such that the diameter increases toward the front so that the front tapered wedge 25 can be inserted, And the first angle adjusting head 23 is fitted into the hemispherical groove 220 of the extension ring 22. The hemispherical groove 220 is formed in the hemispherical groove 220 of the extension ring 22 as shown in FIG.

The PC stranded wires 10 can exhibit a high tensile force to maintain a linear state of the force of pushing the PC stranded wire 10 in the direction opposite to the direction of pushing downward the pliers 21, The first angle adjusting head 23 is formed on the hemispherical groove 220 of the extension ring 22 so that it is difficult to maintain the linearity of the PC stranded wire 10 when an uneven hole is formed, When the installation angle of the PC stranded wire 10 fastened to the first angle adjusting head 23 is changed, the rear surface of the hemispherical shape is free to move upward, downward, left, The angle adjustment head 23 is immediately slid along the changing angle of the PC strand 10 so that the back side is moved so that the PC stranded wire 10 maintains a straight line state at any time with the first angle adjusting head 23 without bending, Due to high bearing capacity .

In addition, the first angle adjusting head 23 can absorb vibrations generated during a large-scale ground deformation or an earthquake, thereby preventing damage to components fastened by vibration and deterioration of fastening force of parts.

The head protection cap 24 has a space formed therein so that the extension ring 22 can be received therein and a thread is formed on the inner surface of the rear end so that a plurality of PC strands 10 are fastened by the wedge 25 And the inner surface thread of the head protection cap 24 is screwed on the outer circumferential edge of the extension ring 22 formed on the support plate 21, 21) so as to protect the exterior from external environment such as rainwater.

The corrugated pipe 30 surrounds the PC strand 10 and the grout re-injection pipe 11, which are installed in a spiral state in the fusing section of the perforation hole, from the outside so that the inside thereof is hermetically sealed. To increase the compressive force and the frictional force with respect to the ground, thereby increasing the tensile force.

The inner bottom body connecting member 40 to be described later is provided at the rear end of the corrugated tube 30 and the space between the corrugated tube 30 and the PC stranded wire 10 is finished with silicone C to form a corrugated tube 30 The air inside the corrugated pipe 30 can be discharged to the outside in order to smoothly inject the grout material into the corrugated pipe 30 from the grout reinfusion pipe 11 installed inside the corrugated pipe 30 An air discharge hose (60) of a predetermined length is inserted through the corrugated pipe (30) from the inside to the front end.

The grout material injected from the inside of the corrugated pipe 30 is combined with the PC stranded wire 10 in a spiral state to prevent corrosion of the PC stranded wire 10 and at the same time is firmly connected to the corrugated pipe 30, So that it can maintain stability even under large-scale ground deformation or earthquake.

As shown in FIG. 5, the inner bottom connecting member 40 is installed at the rear side of the corrugated pipe 30 and has a rear end of the PC strand 10 inserted into the inner side. The rear end of the PC strand 10 is free And is composed of a fixing ring 41, a second angle adjusting head 42 and an inner lower body connecting cap 43 which are tightened so as to be adjustable in angle.

The fixing ring 41 is installed on the rear side of the corrugated pipe 30 and is formed with an inner hollow shape extending for a predetermined length so that the rear end of the PC stranded wires 10 is penetrated and a hemispherical groove 410 is formed in the rear inner side And a thread 412 is formed on the outer periphery of the inner lower body coupling cap 43 to be described later.

At this time, the rear end portion of the PC strand 10 positioned inside the fixing ring 41 is installed in a covered state for preventing corrosion and for adjusting the angle, and the grout material injected in the corrugated pipe 30 is connected to the inner lower body connecting member The grout material is injected only into the inside of the corrugated pipe 30 and the stationary ring 41 is filled with the silicon C so that the gap between the front end of the stationary ring 41 and the PC stranded wires 10 is filled with silicon 41 to prevent the inflow thereof.

The second angle adjusting head 42 is provided with a plurality of PC strands 10 passing through the fixing ring 41 so as to fasten the rear end of the PC strands 10 through the wedge 44, And the front surface of the fixing ring 41 is formed into a hemispherical shape corresponding to the hemispherical groove 410 of the fixing ring 41 so that the front surface of the fixing ring 41 is free from an angle with respect to the hemispherical groove 410 of the fixing ring 41 So as to be adjusted.

That is, the second angle-adjusting head 42 has the same function as the first angle-adjusting head 23 and is coupled to the hemispherical groove 410 of the stationary ring 41, The second angle adjusting head 42 is slid in the hemispherical groove 410 of the stationary ring 41 when the rear end mounting angle of the PC strand 10 is changed, The front side is moved along the changing angle of the PC stranded wire 10 so that the rear end of the PC stranded wire 10 can maintain the straight state at any time with the second angle adjusting head 42 without bending.

Accordingly, a plurality of PC stranded wires 10 are fastened to the first angle adjusting head 23 and the second angle adjusting head 42, respectively having front and rear ends freely adjustable in an up, down, left, (Hereinafter referred to as "bony type"), which prevents the PC strand breakage even during large-scale ground deformation or earthquake, prevents damage to other connected parts, The first angle adjusting head 23 and the second angle adjusting head 42 can absorb vibrations generated during a large scale ground deformation or an earthquake, And the deterioration of the fastening force of the parts can be prevented.

The inner lower body connection cap 43 is formed with a space portion to receive the fixing ring 41 inwardly and a thread is formed on the inner surface of the front inner side to be threadably engaged with the outer periphery of the fixing ring 41, A connecting protrusion 430 whose inner side is penetrated and reduced in width is protruded by a predetermined length so that the tip of the inner bottom body 50 is firmly fitted to the outer side of the connecting protrusion 430.

The inner surface of the connecting protrusion 430 is formed with a thread so that a thread is formed on the outer circumference and a nail 55 installed inside the inner bottom body 50 is tightly threaded to the inside of the connecting protrusion 430 do.

The wedge-shaped inner lower body 50 is provided on the rear side of the inner lower body connecting member 40. The wedge-shaped inner lower body 50 is formed with a wedge-shaped protrusion 500 whose width becomes narrower toward the end, A plurality of wedge-shaped vanes 510 projecting in a radial direction are formed in the longitudinal direction to facilitate insertion into the perforation holes and to simultaneously increase the compressive force and the frictional force with respect to the ground.

The inner bottom body 50 is formed in a hollow shape so that a nail 55 having a threaded outer periphery is inserted through the inner lower body 50. The inner bottom body 50 and the nail 55 are formed with through- The nails 55 are formed at the positions where the holes 500 are mutually communicated with each other and the fastening members 56 made of bolts and nuts are fastened to the through holes 520 by connecting the inner lower body 50 and the nails 55, Tightly integrated with the inner side of the inner lower body (50).

Although the inner lower body 50 is shown as an integral structure in the drawing, the inner lower body 50 can be manufactured in a structure in which the body is divided into two bodies in the longitudinal direction when the mold is formed, The nail 55 is installed and then the fastening member 56 made of bolts and nuts is fastened to each of the through holes 520 so that the divided inner lower body 50 and the nail 55 can be integrally assembled at once.

6 and 7, a bony anchor construction method capable of absorbing vibration of an earthquake using the bony anchor assembly according to the present invention constructed as described above will be described as follows.

First, a perforation hole A having a horizontal plane and an inclination is formed on the original slope 1 which is not reinforced.

Thereafter, the PC stranded wire 10, the grout reinfusion tube 11, the corrugated pipe 30, the inner bottom body connecting member 40, the nail 55 and the inner bottom body 50 are assembled in the assembled state in the perforation hole A, .

When the anchor body is completely inserted, the grout material is filled into the corrugated pipe 30 through the grout material injection pipe 11 provided in the corrugated pipe 11. [

Thereafter, a graphite re-injection tube (not shown) for external injection is inserted into the perforation hole A outside the anchor body, and a grout material is introduced into the perforation hole A through a grout reinjection tube (not shown) Filling grout reinjection tube (not shown) for external injection and curing the grout material.

The grooved material is cured in the inside of the corrugated pipe 11 and the perforation hole A so that the pressure plate 21 is provided at the inlet side of the perforation hole A, The first angle adjusting head 23 is inserted into the hemispherical groove 220 and the tip of each PC strand 10 is passed through each fixing hole 230 formed in the first angle adjusting head 23 to form a tip The installation angle of which is adjusted.

Then, the angle of the first angle adjusting head 23 is adjusted so that the tip end side of the PC stranded wire passing through each fixing hole 230 of the first angle adjusting head 23 is aligned with the angle of the perforation hole.

After the angle adjustment of the first angle adjusting head 23, the wedge 25 is fitted to each fixing hole of the first angle adjusting head with the wedge fitted to the front end of each PC stranded wire 10, and a wedge (not shown) 25 are rotated to perform tensioning of the PC stranded wire 10.

This allows the first angle-adjusting head 23 and the second angle-adjusting head 42 to slide even when an irregular slope, an earthquake, or a large-scale ground deformation occurs and the front and rear ends of the PC strand 10 are always straight So that the maximum tensile force can be exerted at all times due to the axial alignment of the force of the PC stranded wire (10). At the same time, as the tensile force of the PC stranded wire is applied, the wedge- shaped inner lowered body becomes stronger due to the compressive force and frictional force with the ground So that it is possible to effectively reinforce and support the unstable or fragile ground.

Also, vibration generated by an earthquake or a large scale ground deformation can be absorbed by the first angle adjusting head and the second angle adjusting head, thereby preventing damage to the anchor body and maintaining the fastening force of the anchor body.

After the tension is completed, the head protection cap 24 is fastened to the extension ring 22 of the pressure plate 21, and the head is finished to complete the construction of the anchor assembly.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

10-PC Strand
20-head member
21-plate
22-Extension Ring
23-First Angle Adjustment Head
24-head protection cap
25-wedge
30-Corrugated tube
40-inner lower body connecting member
41- Fixing ring
42- Second Angle Adjustment Head
43- Internal lower connection cap
44-Wedge
50-lower body
55-Nail

Claims (7)

A plurality of PC stranded wires (10) arranged side by side with grout reinjecting pipes (11) for injecting grout material and installed in the perforation holes of the ground; A head member (20) closely attached to the ground and having a distal end portion of the PC stranded wire (10) threadably engaged therewith; A corrugated pipe (30) surrounding the PC stranded wire and the grout reinforcement pipe in a non-covered state in the fixing section of the perforation hole; An inner lower body connecting member 40 installed at the rear side of the corrugated pipe 30 and having a rear end of a PC stranded wire inserted therein through an angle adjustable manner; A wedge-shaped protrusion 500 which is provided at the rear side of the inner lower body connecting member 40 and has an inner hollow shape so that the nail 55 can penetrate through the inner protrusion 500, And a wedge-shaped inner bottom body (50) in which a plurality of wedge-shaped vanes (510) are radially formed,
The head member 20 includes a support plate 21 which is formed in an inner hollow shape and closely attached to the ground so that an extension ring 22 having a hemispherical groove 220 formed inside is formed forward and a PC stranded wire 10 is inserted through the support member 20, ,
A plurality of fixing holes 230 are formed to penetrate the PC strand 10 through which the tip end is penetrated by the wedge 25 and the rear side is formed in a hemispherical shape so that an angle A first angle-regulating head 23 to which adjustment is freely combined,
And a head protection cap (24) threaded into the outer periphery of the extension ring (22) of the pressure plate (21)
The inner lower body connecting member 40 is provided at the rear side of the corrugated pipe 30 and is provided with a gap between the front end and the PC stranded wire 10 with silicone to prevent inflow of the grout into the inner side, A stationary ring 41 formed with a groove 410,
A plurality of fixing holes 420 are formed to penetrate the rear end of the PC strand 10 and to fasten the rear end of the PC strand 10 through the wedge 44, A second angle adjusting head 42 which is freely angularly coupled to the hemispherical groove 410 of the first and second cams 41,
And an inner lower body connecting cap 43 having a tip end threadably joined to the outer periphery of the fixing ring 41 and a connecting protrusion 430 protruding rearward so as to fasten the tip of the inner bottom body 50 to the rear end center Anchor assembly. delete delete delete delete The method according to claim 1,
The check hose 110 having a diameter smaller than that of the grout reinfusion pipe 11 is inserted into the grout reinfusion pipe 11 so that the check pin 115 for checking the installation length of the PC stranded wire 10 can be inserted therein , And a check hose cover (112) is provided at the tip of the check hose (110) to block the inflow of the grout material into the check hose (110). An anchor construction method capable of absorbing vibrations of an earthquake using a bony anchor assembly according to any one of claims 1 and 6,
A perforation hole forming step of perforating the perforation hole (A) on the ground for installing the anchor assembly;
An assembling step of inserting a PC stranded wire, a grout reinfusion tube, a corrugated pipe, an inner bottom body connecting member, an inner bottom body, and a nail assembly into the perforation hole A;
Filling the grout material with the grout material by filling the grout material with the grout material injection tube assembled into the assembly;
Filling the grout material into the perforation hole (A), filling the grout material into the perforation hole (A), filling the grout material inside the perforation hole (A);
After removing the grout re-injection tube for external injection, a pressure plate is installed on the ground of the inlet of the perforation hole (A), and the first angle adjusting head is inserted into the hemispherical groove of the extension ring formed on the pressure plate, A step of installing a pressure plate installed on the pressure plate so that the installation angle of the front end of the PC strand is passed through the PC stranded wire;
Adjusting the angle of the first angle adjusting head to adjust the angle of the first angle adjusting head so that the PC stranded wire passing through each fixing hole of the first angle adjusting head is in line with the hole angle of the hole;
A wedge mounting step of mounting a wedge at the tip of each PC stranded wire and installing the fixed wedge of the first angle adjusting head;
A PC strand tensioning step of rotating the wedge to tension each PC strand;
And a head protection cap mounting step of fastening the head protection cap to the thread of the extension ring so as to cover the extension ring, wherein the anchor construction method is capable of absorbing vibration of the earthquake using the ankle anchor assembly.

Images