KR101454813B1 - Helix composite pile connecting device and the construction method therefor - Google Patents

Abstract

The present invention relates to a fastening device for a helical pile which can easily connect a helical pile to a helical pile which is rotated and inserted into a ground while connecting a helical pile having a limited length, The fastening device forms a fastening hole in the helical pile head, and the fastening hole is inserted into the adapter so as to be fastened by one-touch, and the adapter is connected to the fastening metal bracket so as to rotate the fastening metal bracket, .

Description

TECHNICAL FIELD [0001] The present invention relates to a fastening device for a helical pile,

The present invention relates to a fastening device for a helical pile and a construction method thereof. More particularly, the present invention relates to a fastening device for a helical pile which can more easily connect a helical pile to a helical pile which is rotatably inserted into a ground while connecting helical piles having a limited length.

One method of constructing piles for supporting structures or reinforcing piles for ground reinforcement is to use micro piles having a relatively small diameter.

FIG. 1A is a sectional view of a conventional helical pile 20, wherein the helical pile is a generally hollow pile-shaped pile, and a plurality of helical rotary blades 21 are vertically spaced apart from the helical pile 20 20) by rotating it on the ground.

FIG. 1B is a perspective view of a rotary wing 11 of a conventional helical pile 10. FIG. That is, the rotary vane 11 is formed on the outer circumferential surface of the helical pile 10 so as to cut a part of the ring-shaped rotary vane portion and vertically cut away in the vertical direction, So that the ground G is rotatably inserted while being shear-destroyed.

After the helical pile 20 is inserted into the ground, the head of the helical pile 20 is fixed to the support plate (not shown) by using a fixing nut 50.

When the helical pile 20 is to be connected to each other by a limited length (for reasons of construction, transportation, etc.), the connection ends of the helical piles 20 are inserted to overlap each other, It is common to use fastening members 40 such as bolts and nuts.

In addition, in the operation of connecting the helical pile 10 having a limited length by using the fastening member 40 while rotating it, the helical pile head is installed on the ground by rotating the helical pile using a rotating device Conventionally, since the head of the helical pile has to be connected to the head of the rotating device, it is pointed out that the workability is very low and causes air delay.

Accordingly, the present invention provides an adapter which can mechanically connect a helical pile to a fixing metal, thereby dramatically improving the workability of the helical pile, thereby providing a more efficient and economical helical pile construction And an object of the present invention is to provide a fastening device and a construction method thereof.

Another object of the present invention is to provide a fastening device for a helical pile and a method of constructing the same for solving the problem that the helical pile is very vulnerable to horizontal resistance.

In order to achieve the above object,

First, a fastening hole is formed in the helical pile head, the fastening hole is inserted into the adapter to be fastened by one touch, and the adapter is connected to the fastening metal bracket so as to rotate the fastening metal bracket so that the helical pile is simply inserted .

Secondly, by injecting solidification material (cement, etc.) around the conventional helical pile, it is possible to secure the horizontal resistance by increasing the horizontal resistance area by integrating the hardened material and disturbed ground and the helical pile.

The helical pile according to the present invention can connect a plurality of helical piles in a simple and quick manner and rotate them on the ground. Thus, it is possible to construct a very quick helical pile and to connect a helical pile mechanically, It is possible to construct a helical pile having excellent performance.

In addition, the present invention can compensate for the disadvantages of the conventional helical pile since the compound resistance can be secured by forming a composite pile by being integrated with the disturbed surrounding ground when constructing the helical pile using the composite hard coat.

FIG. 1A is an exploded perspective view of a conventional helical pile,
FIG. 1B is a perspective view of a rotary blade of a conventional helical pile,
2B and 2C are an exploded perspective view and an operation view of a helical pile and a fastening device according to a first embodiment of the present invention,
FIGS. 3A, 3B and 3C are exploded and assembled perspective views and operation views of a fastening device for a helical pile according to a second embodiment of the present invention,
4 is an exploded perspective view of a fastening apparatus for a helical composite pile according to a third embodiment of the present invention,
5A, 5B, 5C, and 5D are flowcharts of a method for installing a fastening device for a helical pile of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

[Fastening device for helical pile (100) of the present invention]

[Example 1]

FIGS. 2A, 2B and 2C are an exploded perspective view and a functional diagram of the helical pile and the fastening device according to the first embodiment of the present invention, respectively.

2A and 2B are exploded perspective views of a fastening device for a helical pile 100 having a helical pile 100 and a rotating blade 110 of the present invention.

First, as shown in FIG. 2A, the helical pile 100 is a pile having at least one or more rotating blades 110 formed on the outer circumferential surface of a hollow pile. At this time, the rotary vane portion 110 is formed integrally with the pipe-shaped pile, for example, in a state where the circular ring is cut and the cut portion is vertically spaced.

2A and 2B, a fastener 120 is mounted on the head of the helical pile 100 such that the two fastening blocks 121 are opposed to the outer circumferential surface of the head portion of the helical pile. And the fastening block 121 is fastened to the helix pile head with the fastening bolt 122 so that the fastener 120 is mounted on the head of the helical pile 100.

At this time, the fastener 120 has a function of inserting the head of the helical pile 100 into the adapter 300 mounted on the fixing bracket 200 to be described later.

It can be seen that the fastener 120 has a through hole corresponding to the head of the helical pile having the through-hole formed by the vertical fastening block, and the bottom surface is formed with the convex hole 123 Able to know.

It can be seen that the two convex spheres 123 are formed to be continuous with each other.

The fastener 120 is formed on the head of the helical pile 100 and inserted into the adapter 300 to be described later so that the convex male threaded portion 123 is caught by the concave female threaded portion 324 in the adapter, The helical peg is fastened with one touch to the bracket.

Referring to FIG. 2B, the fixing bracket 200 and the adapter 300 can be identified.

Referring to FIG. 2B, the helical pile 100 having the fastener 120 mounted on the head is mounted on the fixing bracket 200 by the adapter 300. The fixing bracket 200 is formed of a cylindrical steel material (Not shown), the helical pile 100 connected by the adapter 300 is rotatably inserted into the ground. In order to secure the rotational force effectively, the fixing bracket 200 is provided with a helical pile 100 having a diameter larger than the diameter of the cylindrical cylindrical block.

The connection cylinder 210 is formed on the bottom surface of the fixing bracket 200 and a horizontal through hole is formed in the connection cylinder 210 so that the upper adapter 310 of the adapter 300, Is connected to the connecting cylinder 210 by a connecting bolt.

When the fixing bracket 200 rotates, the adapter 300 connected by the connection bolt can rotate together.

The adapter 300 is formed to include an upper adapter 310 and a lower adapter 320 as shown in FIG. 2B.

The upper adapter 310 is formed by a cylindrical body 311 and a lower flange 312 at the bottom of the cylindrical body 311 so that the cylindrical body 311 is inserted into the connection cylinder 210 of the fastening metal 200 And a horizontal through hole corresponding to the horizontal through hole formed in the connecting cylinder 210 is also formed so that the connecting bolt is coupled through the horizontal through holes so that the upper adapter 310 is connected to the fixing bracket 200.

The lower flange 312 is a horizontal plate having a diameter larger than that of the cylindrical body portion 311, and a vertical connection hole is formed along the periphery thereof.

Next, the lower adapter 320 is formed to include an upper flange 321 and a fixing cylinder 322 extending downward from the center bottom surface of the upper flange 321.

At this time, reinforcement pieces 325 are formed on the outer circumferential surface of the fixing cylinder 322 and the bottom surface of the upper flange 321.

First, the upper flange 321 is a horizontal plate having the same diameter as the lower flange 312 of the upper adapter 310, and a vertical connection hole is also formed along the outer periphery.

The upper and lower adapters are connected to each other by the connection bolts inserted into the vertical connection holes of the upper flange of the lower adapter and the lower flange 312 of the upper adapter.

2B and 2C, the fixing cylinder 322 is formed in a cylinder-shaped cylinder shape and has a fastening groove 323 extending upward from the bottom surface thereof to allow the fastening tool 120 inserted therein to be inserted into the fixing cylinder 322, And is formed in the body portion. The fastening groove 323 is formed at a height smaller than the entire height of the fixing cylinder.

At this time, a concave female hooking hole 324 is formed in a lower portion of the coupling groove 323. The coupling hole 323 is formed as a block body horizontally extending below the coupling groove 323, and a semicircular concave portion is formed on the upper surface of the block body The helical pile 100 is inserted into the adapter 300 so that the helical pile 100 is caught while the convex male threaded portion 123 of the fastening tool 120 contacts the upper surface of the concave female threaded portion 324. [

When the helical pile 100 is inserted into the lower adapter 320 and then the helical pile is lowered again, the bottom surface of the semicircular convex portion of the convex male threaded portion 123 abuts on the upper surface of the semicylindrical concave portion of the concave female threaded portion 324 It is possible to make the helical pile easily caught by the adapter while being caught.

Thus, the transverse width and height of the fastening groove 323 are formed larger than the height and the transverse width of the fastening hole 120, so that the helical pile is easily caught by the adapter.

The two fastening grooves 23 are formed in the lower portion of the fixing cylinder so as to face each other diagonally so that the helical pile can be securely hooked to the adapter.

In Embodiment 1, it can be seen that the concave arm fastening openings 324 are arranged diagonally (asymmetrical) with respect to each other below the one fastening groove. However, in Embodiment 2 described later, (Symmetrical) in such a manner that two of them are hammered together.

Thus, when the fixing bracket 200 is rotated by a rotating device (not shown), the helical pile 100 caught by the adapter 300 can rotate together.

Further, as shown in FIGS. 2B and 2C, a connection reinforcing plate 330 is formed on the bottom surface of the fixing cylinder 322 so that the head and the fastening hole of the helical pile can be precisely inserted into the lower adapter 320 can do.

In other words, the connection reinforcing plate 330 in the shape of a circular plate formed at the center of the circular groove and the groove for the fastener having a rectangular shape formed on the side of the circular groove so as to penetrate the tubular body 130 of the helical pile and the fastening hole 120 Can be integrally formed on the bottom surface of the fixing cylinder 322. [

Since the function of engaging the helical pile with the helical pile fastening device when the helical pile is pulled out from the ground is the main function, the lower adapter 320 The fastening groove 323 is formed in the fixing cylinder 322 of the fastening block 120. The fastening block 321 is not formed with the concave female threaded hole 324, 123 are not formed, there is no problem in rotating the helical pile using the fixing bracket.

[Example 2]

FIGS. 3A, 3B and 3C are an exploded perspective view and an operational perspective view, respectively, of a fastening device for a helical pile according to a second embodiment of the present invention.

The second embodiment is different from the first embodiment in that the helical pile 100 on which the fixing bracket 200, the adapter 300 and the fastener 120 are mounted is provided as it is, And two concave female locking holes 324 are formed in the lower portion of the fixing cylinder so as to face each other, which is different from the first embodiment.

It can be said that both the fasteners can be hooked to the fastening grooves of the lower adapter.

As shown in FIGS. 3A and 3B, the helical pile 100 may also be a pile shaft having at least one or more rotating blades 110 formed on the outer circumferential surface of the tubular body 130.

The fastening bolt 120 is mounted on the head of the helical pile 100 and the two fastening blocks 121 are disposed to face each other on the outer circumferential surface of the head of the helical pile. So that the fastening tool 120 is mounted on the head of the helical pile 100.

As shown in FIG. 3B, the fastener 120 is also formed with a through hole corresponding to the head of the helical pile having a through-hole formed by a vertical fastening block, and a bottom surface is formed with a convex hole 123.

Further, it can be seen that the convex male part 123 also has two semicircular convexes formed continuously with each other.

This fastener 120 is also formed on the head of the helical pile 100 and inserted into the adapter 300 to be described later so that the convex hole 123 is caught by the concave arm hole 324 in the adapter .

3A and 3B, the fixing bracket 200 and the adapter 300 can be identified.

3C, it can be seen that the helical pile 100 having the fastener 120 mounted on the head is mounted on the fastening metal 200 by the adapter 300.

It is to be noted that the connection cylinder 210 is also formed on the bottom surface of the fixing bracket 200 and the horizontal adapter is formed so that the upper adapter 310 of the adapter 300 described below is connected to the connection cylinder 210 .

The adapter 300 is also formed with an upper adapter 310 and a lower adapter 320.

The upper adapter 310 is formed of a cylindrical body 311 and a lower flange 312 at the bottom of the cylindrical body 311 so that the cylindrical body 311 is inserted into the connecting cylinder 210 of the fixing metal, A horizontal through hole corresponding to a horizontal through hole formed in the upper case 210 is also formed so that the connecting bolt is coupled through the horizontal through holes so that the upper adapter 310 is connected to the fixing bracket 200.

The lower flange 312 is also a horizontal plate having a diameter larger than that of the cylindrical body portion 311, and a vertical connection hole is formed along the outer periphery thereof.

Next, the lower adapter 320 is also formed including an upper flange 321 and a fixing cylinder 322 extending downward from the center bottom of the upper flange 321.

At this time, it is understood that reinforcement pieces 325 are formed on the outer circumferential surface of the fixing cylinder 322 and the bottom surface of the upper flange 321.

The upper flange 321 is a horizontal plate having the same diameter as the lower flange 312 of the upper adapter 310 and a vertical connection hole is formed along the outer periphery thereof so that the lower flange 312 of the upper adapter 310 and the lower flange 312 of the lower adapter The connecting bolts inserted in the vertical connection holes of the upper flange also allow the upper and lower adapters to be connected together.

Next, the fixing cylinder 322 is also formed in a cylinder-shaped cylinder shape, and a fastening groove 323 extending upward from the bottom surface is formed in the fixing cylinder body so that the fastening tool 120 can be inserted. It can be seen that the fastening groove 323 is formed at a height smaller than the entire height of the fixing cylinder.

At this time, a recessed arm insertion hole 324 is formed in the lower portion of the coupling groove 323. The coupling hole is formed as a block body horizontally formed at the lower portion of the coupling groove, and a semi-circular recessed portion is formed on the upper surface of the block body, The head of the helical pile is inserted into the lower adapter 320 to be hooked, as shown in FIG. 3C.

When the helical pile is inserted into the lower adapter and then the helical pile is lowered again, the semicircular convex portion of the convexity hole 123 is caught in the upper end of the semicircular concave portion so that the helical pile can be easily caught by the adapter same.

Unlike the first embodiment, four recessed female threaded holes 324 are formed in the lower portion of the fixing cylinder of the fixing cylinder so as to be opposed to each other, so that the helical pile adapter can be securely attached to any one of the female threaded fasteners.

Further, a connection reinforcing plate 330 can be further formed on the bottom surface of the fixing cylinder 322 to set the position so that the head portion of the helical pile and the fastening hole are correctly inserted into the lower adapter 320.

In other words, the connection reinforcing plate 330 in the shape of a circular plate having the rectangular groove-shaped fastener groove formed at the side of the circular groove and the circular groove is formed at the center so that the body 130 of the helical pile and the fastening hole 120 are penetrated It can be integrally formed on the bottom surface of the cylinder 322.

Also in the second embodiment, the function of engaging the helical pawl with the helical pile fastening device when the helical pawl is pulled out from the ground is the main function Only the fastening groove 323 is formed in the fixing cylinder 322 of the lower adapter 320 and the fastening hole 323 is formed on the bottom surface of the fastening block 121 of the fastening hole 120 There is no problem in rotating the helical pile using the fixing bracket, even if the convexity hole 123 is not formed.

[Example 3]

4 is an exploded perspective view of a fastening device for a helical pile according to a third embodiment of the present invention.

The third embodiment is a modification of the first embodiment or the second embodiment, and FIG. 4 is based on the first embodiment.

Embodiment 3 is a case where elastic springs 350 are further formed on the upper portion of the fixing grooves in Embodiments 1 and 2, and the rest of the constitution is the same, so a description thereof will be omitted.

In this case, the elastic spring 350 is inserted into the fixing groove and has a height such that the upper end of the elastic spring 350 is in contact with the bottom surface of the lower adapter and extends to the center of the fixing groove. In particular, a supporting plate is formed on the bottom surface of the elastic spring 350, The upper surface of the body 130 is supported by the support plate so that the helical pegged by the elastic spring 350 more reliably in the fastening groove is not separated from the fastening groove.

That is, when the helical pile is lifted, the elastic spring 350 can provide an elastic force to prevent the helical pile 100 from being seated in the fixing groove 323 and falling down.

Thus, in the present invention, the helical pile can be rotated and inserted into the ground using a rotating device in a state where the helical pile is hooked to the fixing metal by an adapter at one-touch.

Also in the third embodiment, the function of engaging the helical pawl with the helical pile fastening device when the helical pawl is pulled out from the ground is the main function Only the fastening groove 323 is formed in the fixing cylinder 322 of the lower adapter 320 and the fastening hole 323 is formed on the bottom surface of the fastening block 121 of the fastening hole 120 There is no problem in rotating the helical pile using the fixing bracket, even if the convexity hole 123 is not formed.

[Method of constructing fastening device for helical pile (100) of the present invention]

The construction method will be described with reference to the third embodiment.

First, as shown in FIG. 5A, the helical pile 100 having the fastener 120 mounted thereon is rotated to reach a predetermined depth H1 from the ground surface.

In this case, the fixing bracket 200 and the adapter 300 according to the first, second, and third embodiments can be used. In particular, in FIG. 5A, the fixing bracket 200 according to the first embodiment, Is used.

The depth H1 is not a numerical value but may be a first construction depth depending on the ease of construction and the conditions of the site based on the final depth (H).

Thus, the ground from the ground surface to the depth H1 becomes disturbed, and the cylindrical guide unit 400 is placed in a disturbance near the ground surface in order to prevent the disturbed ground near the ground surface from collapsing, To the ground.

It can be seen that the body part 410 constituting the guide part is inserted in the upper part of the disturbed ground near the ground surface and the upper flange part 420 is set in contact with the surface of the ground surface.

Next, as shown in FIG. 5B, the composite solid solution 500 is injected into the guide part 400.

Generally, when the helical pile 100 is rotatably inserted into the ground, the disturbed ground becomes the ground surface, and the composite material 500 remains in the ground without flowing out. Therefore, it is mixed with the remained disturbed ground and injected with high solubility to be solidified. There is a limit in the disturbed ground where the deposition material reacts, so that the high solubility material capable of reacting with the disturbed ground from the ground surface to the depth (H1) .

Such a high solubility material can be obtained by using a combination of cement, sand, water, viscoelastic admixture, and high quality gypsum, and it is said that there is a point to cement the soil of the ground instead of simply using the grout material.

After the hardening of the hardening material is completed, the disturbed ground is hardened and hardened ground is formed around the helical pile, so that the helical pile can be constructed.

Accordingly, the present invention is characterized in that the high solubility material is referred to as a composite high solubility material (500).

Next, as shown in FIG. 5C, another helical pile is connected to the helical pile 100 to insert the helical pile into a deeper position. In this case, since the ground around the helical pile mixed with the compound hardener is not yet fully cured, the ground in which the mixed hard coating material is mixed by the rotation insertion can be moved downward, reaches the additional depth (H2) Thereby injecting the solid solution 500.

First, the ground in which the mixed hull 500 is mixed with the mixed hull mixed with the mixed hull is mixed with the ground, so that the ground can be secured upside down over time.

As shown in FIG. 5D, after the helical pile is connected to the final depth (H3) while rotating, the composite pavement 500 injected over the entire depth (H = H1 + H2 + H3) It can be seen that the hardened pile is formed by the mixed hardening of the soil.

Therefore, the composite helical pile according to the present invention can resist the horizontal force due to the horizontal resistance cross-sectional area due to the diameter of the surrounding pile, not the diameter of the helical pile, at the upper end, It is possible to compensate the shortcomings of the pile. When the construction of the final composite helical pile is completed, the guide part 400 can be removed and reused.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: Helical peg
110:
120: fastener
121: fastening block
122: fastening bolt
130:
200: Fixing bracket
210: connecting cylinder
300: Adapter
310: upper adapter
311: Cylindrical body part
312: Lower flange
320: Lower adapter
321: Upper flange
322: Fixing cylinder
323: fastening groove
324: Concave female stopper
325:
330: Connection reinforcing plate
400: guide portion
410: body portion of the guide portion
420: upper flange portion of the guide portion
500: Compound payment

Claims (8)

A coupling groove 323 extending upward from the bottom surface so that the coupling hole 120 of the helical pile 100 can be inserted is formed in the form of a cylindrical cylinder connected to the lower portion of the upper adapter 310 connected to the fixed metal fitting 200, A lower adapter 320 including a fixing cylinder 322 formed on the body portion; And
The coupling block 121 is disposed on the outer periphery of the head of the body 130 so as to be opposed to the coupling bolt 122 And a fastening hole 120 in which the fastening block 121 is fastened to the head of the trunk 130 by means of a fastening bolt The helical pile 100 is inserted into the groove 323 so that the helical pile 100 is connected to the fixing bracket 200 and rotated by the adapter 300,
The upper adapter 310 and the upper adapter 310 are connected to each other so that the connection cylinder 210 is inserted into and connected to the upper adapter and the upper adapter 310 is connected to the cylindrical body 210. [ The lower flange 312 is formed on the bottom surface of the cylindrical body portion 311 and the cylindrical body portion 311 is inserted and connected to the connecting cylinder 210 of the fixing metal, (311) having a diameter larger than that of the flat portion (311)
The lower adapter 320 is formed to include an upper flange 321 connected to the lower flange 312 of the upper adapter 310 and a fixing cylinder 322 extending downward at the lower center of the upper flange 321, The fixing cylinder 322 is provided at its bottom surface with a circular groove and a groove for a fastener in the shape of a rectangle formed on the side of the circular groove so that the tubular body 130 of the helical pile and the fastening hole 120 are passed, To thereby form a connection reinforcing plate (330) of the shape of the helical pile. delete The method according to claim 1,
The fixing cylinder 322 of the lower adapter 320
A concave female locking hole 324 extending horizontally is formed on the lower inner side surface of the coupling groove 323, a semicircular concave portion is formed on the upper surface of the block body,
A convex male threaded portion 123 is formed on the bottom surface of the fastening block 121 of the fastener 120 so that the convex male threaded portion 123 of the fastener 120 is inserted into the concave arm 123 of the lower adapter 300, (324) of the helical pile. delete The method according to claim 1,
The fixing grooves formed in the fixing cylinder are formed to face each other on the body and the concave female locking holes 324 formed in the inner side of the lower side of the locking groove are formed in each of the locking grooves or in a lower portion of one locking groove, And an elastic spring (350) is further provided on the bottom of the upper flange of the lower adapter to support the body portion (130) of the helical pile inserted into the fixing cylinder on the support plate formed under the elastic spring Fastening device. And a coupling block 121 is disposed on the head so as to be opposed to the outer circumferential surface of the head portion 130 of the body portion 130, The helical pile 100 having a fastening hole 120 for fastening the fastening block 121 to the head of the trunk 130 by the fastening bolt 122,
And injecting the composite solidification material (300) from the ground surface into the disturbed ground by the rotation insertion,
The rotational insertion of the helical pile
A fixing bracket 200 having a connecting cylinder 210 formed on its bottom surface;
An upper adapter 310 to which the connecting cylinder 210 is inserted and connected; And a coupling groove (323) extending upward from the bottom surface of the cylinder so as to allow the coupling hole (120) of the helical pile (100) to be inserted is formed in a fixing cylinder The head of the helical pile is inserted into the fixing cylinder 322 of the fastening device for a helical pile including the adapter 300 including the lower adapter 320 including the lower adapter 320, Is inserted into the coupling groove 323 of the adapter 300 so that the helical pile 100 is connected to the fixing bracket 200 and rotated,
The fixing cylinder 322 of the lower adapter 320 is formed with a block-shaped concave female locking hole 324 extending horizontally on the lower inner side surface of the coupling groove 323, and a semi-circular recessed portion is formed on the upper surface of the block body And a convex male threaded portion 123 is formed on a bottom surface of a fastening block 121 of the fastening hole 120 so that a convex male threaded portion 123 of the fastening hole 120 is formed in the lower portion of the lower adapter 300 And is engaged with the concave female locking hole (324). delete The method according to claim 6,
The helix pile 100 is sequentially rotated to the final depth so that the disturbed ground above the rotary vane portion is sequentially cured by the composite hose. The disturbed ground to which the composite hose is injected is integrated vertically And,
The cylindrical guide portion 300 is inserted into the disturbed ground near the ground surface so as to prevent the disturbed ground near the ground surface from being collapsed so as to inject the composite hard coating material. Characterized in that the method for constructing a fastening device for a helical pile is provided.

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