KR102464394B1 - Driving rod for forming reinforced part of piles - Google Patents

Abstract

The present invention rotates a cutting arm equipped with a discharge part into the supporting ground of the ground to cut and pulverize the ground, and seat the tip of the pile on the upper part of the expanded tip reinforcement formed by mixing the injection material, without penetrating the pile to the supporting ground. It is about a rotary penetration rod for forming an enlarged tip reinforcement part of a pile that can obtain a greater bearing capacity than an existing pile.
The present invention relates to a rotary penetration rod for forming an enlarged tip reinforcement part of a pile of a pile, wherein a cutting part is provided in the rod body to form an enlarged tip reinforcement part of the pile in the underground support ground, wherein the cutting part is the rod body It is located in the middle between the spiral steel sheet for rotation penetration and the spiral steel sheet provided on the outside or at the front or rear end of the spiral steel sheet to protrude outward than the spiral steel sheet for rotation penetration, and the injection material supply path is provided in the longitudinal direction. , characterized in that it is composed of one or more cutting arms communicating with the injection material supply path and having a discharge portion formed on one side for injecting the injection material into the pulverized surrounding ground.

Description

Rotating penetration rod for forming the expanded tip reinforcement part of the pile {Driving rod for forming reinforced part of piles}

The present invention rotates a cutting arm equipped with a discharge part into the supporting ground of the ground to cut and pulverize the ground, and seat the tip of the pile on the upper part of the expanded tip reinforcement formed by mixing the injection material, without penetrating the pile to the supporting ground. It is about a rotary penetration rod for forming an enlarged tip reinforcement part of a pile that can obtain a greater bearing capacity than an existing pile.

Drilling piles, such as PHC piles and cast-in-place piles, drill the ground up to the bedrock to secure the tip bearing capacity, so the drilling depth is very deep. Since the casing installed to protect the hollow wall during the ground drilling process is difficult to penetrate to the depth of the rock, a pneumatic compressor is used together with the casing to prevent the hollow wall from collapsing during the drilling operation, while discharging the excavated soil with compressed air and performing the drilling operation. Conduct.

However, even if the excavated soil is discharged with compressed air, it is unavoidable that slime due to the excavated soil and the like is accumulated on the bottom of the drilling hole.

Therefore, even if the drilling hole is drilled to the bedrock layer, the pile is placed on the excavated slime at the bottom of the drilling hole instead of being directly supported on the bedrock.

Cast-in-place piles have the advantage of almost no civil complaints due to noise or vibration during construction, but hard hitting during construction is impossible. Therefore, the end bearing capacity cannot be expected, so it can only be used as a friction pile.

PHC piles, which are ready-made piles, have a limit in bearing capacity because the excavated slime at the tip of the pile hardens even if light hitting is performed after the pile construction.

On the other hand, there is a helical pile as a representative example of a pile constructed by press-fitting or rotational penetration.

The helical pile is provided with about three helix, which is a spiral disk, at regular intervals on the outer peripheral surface of the pile body. The helical pile is constructed by rotating the pile into the ground and then filling the inside of the pile with cement grout. It exerts its bearing power through the frictional force of the main surface that is expressed between the ground and the adjacent surrounding ground.

These helical piles have low noise and vibration, and are widely used for foundation reinforcement in new construction or remodeling construction because of their excellent economic efficiency and constructability.

Helical piles are usually installed with hydraulic equipment on small-scale equipment such as backhoes and rotate intrusion into the ground. Therefore, the length of the pile is often limited to less than 3m, and a number of helical piles are connected and used according to the depth of penetration. When a helical pile is used for supporting a building, a helix with a diameter of 200 to 350 mm is usually used. At this time, the helix located at the bottom must be supported on a hard rock layer above the weathered rock, and it is difficult to enter the tip of the pile to the weathered rock with the helix provided, so it is difficult to secure the pile bearing capacity. In addition, when a helical pile having a small diameter is used for a stratum passing through a soft stratum, there is a risk of buckling of the helical pile.

In addition, the conventional micropile has higher reliability with respect to the pile bearing capacity than the helical pile. On the other hand, since a micropile is constructed after drilling the ground, a separate drilling machine is required, and a treatment process for floating soil generated during the drilling operation is required, which is cumbersome and requires a lot of construction cost.

In addition, the micropile requires a casing to protect the hollow wall in the section of soft ground such as weathered soil, so it is less economical, and it is necessary to form a perforation hole in the weathered rock with a diameter larger than the diameter of the micropile, so there is a risk of civil complaints due to the inevitable hammer blow.

US 10-2007-0014547 A1

In order to solve the above problems, the present invention is provided at the lower part of the rotary penetration rod penetrating into the ground, and by cutting and grinding the ground and mixing the injection material, a cylindrical pile expanded tip reinforcement part for supporting the tip of individual piles. To provide a rotary penetration rod for forming.

The present invention according to a preferred embodiment relates to a rotary penetration rod for forming an enlarged tip reinforcing part of a pile on a supporting ground in the ground by having a cutting part in the rod body, wherein the cutting part is a spiral steel plate for rotation penetration provided outside the rod body It is located in the middle of the spiral steel sheet or at the front end or rear end of the spiral steel sheet to protrude outward than the spiral steel sheet for rotation penetration, and an injection material supply path is provided in the longitudinal direction, and one side communicates with the injection material supply path It provides a rotary penetration rod for forming an enlarged tip reinforcing part of a pile, characterized in that it consists of one or more cutting arms on which a discharge part for injecting an injection material into the ground surrounding the ground is formed.

delete

The present invention according to another preferred embodiment provides a rotary penetration rod for forming an enlarged tip reinforcement part of a pile, characterized in that the cutting arm is plate-shaped and has the same penetration angle as a spiral steel plate for rotation penetration.

The present invention according to another preferred embodiment provides a rotary penetration rod for forming an enlarged tip reinforcement portion of the pile, characterized in that the discharge portion 522 is provided with a discharge portion outer protective cover on the outside.

The present invention according to another preferred embodiment provides a rotary penetration rod for forming an enlarged tip reinforcement part of a pile, characterized in that the discharge part 522 is composed of three or more discharge holes whose discharge area increases toward the outside.

The present invention according to another preferred embodiment provides a rotary penetration rod for forming an enlarged tip reinforcement of a pile, characterized in that the cutting arm provided in the spiral steel plate for rotation penetration is provided near the tip of the rod body.

In the present invention according to another preferred embodiment, a support steel plate is provided at a height higher than the cutting arm on the outside of the front end of the rod body, and a hose for supplying injection material for supplying the injection material to the cutting arm is provided inside the rod body. It provides a rotary penetration rod for forming an enlarged tip reinforcing part of a pile, characterized in that it is provided to be connected to the injection material supply path of the cutting arm by the inlet.

In the present invention according to another preferred embodiment, the support steel plate is provided at a height higher than the cutting arm on the outside of the front end of the rod body, and the injection material for supplying the injection material to the cutting arm is accommodated inside the rod body. It provides a rotary penetration rod for forming an enlarged tip reinforcing part of the pile, characterized in that it is provided.

The present invention according to another preferred embodiment is an expansion of the pile, characterized in that the rotary penetration rod is provided with a fluid discharge unit for maintaining the hollow wall for discharging the fluid for maintaining the hollow wall generated in the process of recovering the rod to the ground It provides a rotary penetration rod for forming the tip reinforcement.

The present invention according to another preferred embodiment provides a rotary penetration rod for forming an enlarged tip reinforcing part of a pile, characterized in that the opening and closing of the fluid discharge part for maintaining the hollow wall is possible.

According to the present invention, there are the following effects.

First, since the expanded tip reinforcement formed in the original ground serves as an expanded foundation for individual piles, the allowable vertical bearing capacity is greater than that of a pile constructed by drilling up to the bedrock, or a press-fitted ready-made pile or helical pile that penetrates the bedrock even if the pile does not penetrate the weathered rock. can be obtained

Second, since the cutting arm is provided to have the same penetration angle as the spiral steel sheet in the middle, tip, or rear end of the spiral steel sheet for rotation penetration, the cutting arm is protected, has additional penetration performance, and at the same time, penetration resistance can be minimized.

Third, after completing the formation of the expanded tip reinforcement in the ground as well as the rotation penetration type composite steel pipe pile, where the formation of the expanded tip reinforcement part of the pile is completed at the same time as the rotation penetration is completed, the cutting arm is recovered to the ground and then ready-made piles or cast-in-place piles The scope of application is very wide as various types of piles such as piles can be installed in the expanded tip reinforcement part of the underground.

Fourth, the pile depth is not deep, so there is no risk of the pile buckling.

Fifth, it is economical because it is used as the main material by cutting and pulverizing the supporting ground to form the expanded tip reinforcement part in the ground, and since it is constructed using the non-baking earth rotation penetration method, the site is clean, and there is little noise and vibration, so there is a possibility of civil complaints. none.

1 is a front view showing a rotary penetration rod provided with a cutting part.
Figure 2 is a side view showing a rotary penetration rod provided with a cutting part.
Figure 3 is a perspective view showing a rotary penetration rod provided with a cutting part.
Figure 4 is a perspective view showing an embodiment in which a protective cover is provided on the cutting arm.
5 is a perspective view showing a state in which an injection material supply path is provided inside the cutting part;
Figure 6 is a perspective view showing a rotary penetration rod provided with a cutting arm and an eccentricity prevention part.
7 is a perspective view showing an embodiment in which a discharge space portion is provided on a spiral steel plate.
Figure 8 is a view showing a state in which the rotary penetration rod is installed as a pile.
9 is a perspective view showing an embodiment in which a discharge part cover is provided.
Figure 10 is a view showing a construction method of a pile equipped with an enlarged tip reinforcement part of the present invention.
11 to 13 are views showing a rotating penetration rod without a supporting steel plate.
14 is a view showing a rotary penetration rod provided with a hose for supplying injection material.
15 is a view showing a rotary penetration rod provided with an injection material receiving portion.

Hereinafter, the present invention will be described in detail according to the accompanying drawings and preferred embodiments.

1 to 3 are views showing a rotary penetration rod provided with a cutting part.

As shown in FIGS. 1 to 3, the rotary penetration rod for forming the enlarged tip reinforcement part of the pile of the present invention is provided with a cutting part 5 in the rod body 4, and the pile 2 is installed in the underground support ground 12. ) relates to a rotary penetration rod 3 for forming an enlarged tip reinforcement portion 6, wherein the cutting portion 5 includes a spiral steel plate 51 for rotation penetration provided outside the rod body 4 and the rotation It is formed to protrude outward from the spiral steel plate 51 for penetration, and an injection material supply passage 521 is provided in the longitudinal direction, and on one side is communicated with the injection material supply passage 521 to inject the injection material into the ground surrounding ground. It is characterized in that it consists of a cutting arm 52 in which the discharge part 522 is formed.

Since the cutting arm 52 is mainly fastened to the middle or rear end of the spiral steel sheet 51 for rotation penetration, the cantilever length of the cutting arm 52 can be viewed as a length protruding from the outside of the spiral steel sheet 51, so cantilever As the lever length is shortened, it is structurally safe and can minimize the rotational penetration resistance.

8 is a view showing a state in which the rotary penetration rod is installed as a pile.

The spiral steel plate 51 for rotation penetration mainly refers to a steel sheet having a spiral shape of about one cycle provided at the tip of the rod body 4 in order to obtain a penetration force at the initial stage of rotation penetration of the pile 2, and rotates like a helical pile. When the penetration rod (3) itself is used as the pile (2), it is also helpful in securing the compressive bearing capacity in the vertical direction, and in the case of a tensile pile, it can also be used as a supporting steel plate for pull-out resistance (FIG. 8).

The discharge part 522 is formed of at least three or more discharge holes formed to be spaced apart from each other in the longitudinal direction on one side of the cutting arm 52 , or one side of the cutting arm 52 is cut in the longitudinal direction of the cutting arm 52 . It may be formed to be long, and it is preferable to form so that the injection material discharge amount increases toward the outside.

It may not be necessary to make a groove in the middle of the spiral steel plate 51 . Because the inner side has a small injection amount, the inner side may be possible only with the discharge hole of the cutting arm 52 provided at the rear end of the spiral steel plate.

The cutting arm 52 is one or more, and may be located in the middle of the spiral steel sheet 51 or at the front end or rear end of the spiral steel sheet 51 in the rotational direction.

When there are two or more cutting arms 52 , one of the cutting arms 52 may be disposed at the front end or rear end of the spiral steel sheet 51 in the rotation direction, and the rest may be arranged at equal intervals in the middle of the spiral steel sheet 51 . .

When the rotary penetration rod 3 is used as the pile body, such as a helical pile, it is preferable to place the cutting arm 51 at the rear end of the spiral steel plate 51 to reduce penetration resistance, and after the enlarged tip reinforcement part 6 is formed. In the case of recovering the rotary penetration rod 3 to the ground, it is preferable to position the cutting arm 52 at the tip of the spiral steel plate 51 because the injection material is discharged while the rotary penetration rod 3 is reversely rotated.

6 is a perspective view showing a rotary penetration rod provided with a cutting arm and an eccentricity prevention unit.

As shown in FIG. 6 , when there is only one cutting arm 52 provided with a discharge part 522 , the cutting arm 52 is placed at the front end or rear end of the spiral steel plate 51 in the rotation direction, which is advantageous for uniform discharge of the injection material. It is necessary to form an eccentricity prevention part 53 (which may be viewed as a cutting arm without a discharge part) for preventing eccentricity on the opposite side of the rotation center to the outside of the spiral steel plate 51 for rotation penetration.

The cutting arm 52 is plate-shaped and may be provided to have the same penetration angle as the spiral steel plate 51 for rotation penetration.

The main reason for attaching the plate-shaped cutting arm 52 to the spiral steel sheet 51 to have the same penetration angle as that of the spiral steel sheet 51 is that penetration resistance is minimized and the cutting arm 52 does not have thickness-wise bending. This is because damage or bending of the cutting arm 52 is prevented during the penetration process.

A plurality of grinding tips protruding in the vertical direction may be placed on the upper or lower portion of the cutting arm 52 so that the injection material is uniformly mixed with the raw ground.

4 is a perspective view illustrating an embodiment in which a protective cover is provided on the cutting arm.

As shown in FIG. 4 , a protective cover 523 may be provided on the outside of the discharge unit 522 .

It is possible to prevent foreign substances from being directly caught in the discharge unit 522 during the rotational penetration operation by the protective cover 523, and even if the foreign material passes through the external protection cover 523, the state in which the foreign substances are tightly caught in the discharge unit 522 Since it does not reach to the injection material, it is possible to easily discharge the injection material by discharging the injection material with the internal injection pressure. In particular, if the diameter of the discharge part is reduced and the injection material is discharged with a strong internal pressure using an injection material pump or the like, the injection material can be easily discharged to the ground by cutting.

5 is a perspective view showing a state in which an injection material supply path is provided inside the cutting part, FIG. 7 is a perspective view showing an embodiment in which a discharge space part is provided on a spiral steel plate, and FIG. 9 is an embodiment in which a discharge part cover is provided. is a perspective view showing

As shown in FIG. 5 , the discharge part 522 may include three or more discharge holes whose discharge area increases toward the outside.

It is possible by a method of configuring the diameter of the discharge hole to increase toward the outside and a method of arranging more discharge holes of the same diameter on the outside.

As shown in FIG. 9, if a discharge part cover 524 with a spring attached to each discharge hole is used, the discharge hole is securely closed during penetration, and when discharge is required, the spring tension and discharge pressure are adjusted. You can make it open as much as you need.

When the cutting arm 52 is installed in the middle of the spiral steel plate 51, a groove (not shown) for securing an injection material discharge space is formed in the spiral steel sheet 51 on the front side of the discharge direction of the inner discharge part 522 or in FIG. As shown in the 1/2 cycle spiral steel plate 51 may be spaced apart from the middle to secure the discharge space 511 through which the injection material is discharged.

Figure 10 is a view showing a construction method of the present invention is provided with an enlarged tip reinforcement portion.

In the present invention, first, the rotary penetration rod 3 is rotated to reach the cutting part 5 of the lower part of the rotary penetration rod 3 to the upper part of the support ground 12, and the rotary penetration rod 3 is rotated to cut it. The support ground 12 is cut and pulverized to a diameter larger than the tip of the pile 2 with the arm 52, while the injection material is injected into the cut and pulverized support ground 12 through the discharge part 522, The mixture is mixed to form an enlarged tip reinforcing part 6 of a cylindrical shape (FIG. 10 (a)).

The injection material may be injected by reciprocating up and down while repeatedly rotating the rotary penetration rod 3 in the forward and reverse directions after cutting and grinding the ground with the cutting arm 5 . Alternatively, while cutting and pulverizing the ground, the injection material may be injected into the cut and pulverized ground at the same time, and in this case, the construction period can be shortened and construction is convenient.

The support ground 12 can be cut and pulverized to a diameter of three times or more of the vertical projection area of the tip of the pile (2).

After forming the enlarged tip reinforcing part 6, the rotary penetration rod 3 is recovered to the ground (FIG. 10 (b)). The recovery of the rotary penetration rod (3) is to be carried out before the hardening of the enlarged tip reinforcing part (6).

After recovering the rotary penetration rod (3), it is possible to repeat the operation of forming the enlarged tip reinforcing part (6) by moving the equipment to another ball.

Finally, the pile 2 is constructed so that the tip end of the pile 2 is mounted on the upper surface of the enlarged tip reinforcement part 6 (FIG. 10 (c)).

That is, the pile 2 is constructed at the position of the expanded tip reinforcement part 6 formed in the ground, and the tip part of the pile 2 is seated on the upper part of the expanded tip reinforcement part 6 .

The cutting arm 52 provided in the spiral steel plate 51 for rotation penetration may be provided near the front end of the rod body 4 .

A plurality of rod bodies 4 are connected and used according to the depth at which the enlarged tip reinforcing part 6 is located. of the rod body (4).

Of course, the length of one rod body 4 may be increased to form the enlarged tip reinforcing part 6 with only one rod body 4, which can also be viewed as the rod body 4 of the tip.

The tip provided at the tip of the rod body 4 at the tip of the rotary penetration is also a necessary part to secure the first penetration position.

11 to 13 are views showing a rotating penetration rod without a supporting steel plate.

As shown in FIGS. 11 to 13 , the rotation penetration rod 3 may be configured without a separate support steel plate 41 outside the rod body 4 .

14 is a view showing a rotary penetration rod provided with a hose for supplying injection material.

A support steel plate 41 is provided at a height higher than the cutting arm 52 on the outside of the front end of the rod body 4, and the inside of the rod body 4 is for supplying an injection material to the cutting arm 52. The injection material supply hose 42 may be provided to be connected to the injection material supply path 521 of the cutting arm 52 by the injection material inlet 43 .

The injection material supply hose 42 is provided by rolling a hose longer than the height from the ground to the support ground in advance in the front end rod body 4, and the cutting arm 52 and injection material supply hose provided in the spiral steel plate 51. The rotary penetration rod (3) provided with (42) can be viewed as one product.

When the rotary penetration rod 3 is a helical pile, a spiral-shaped helix may be the supporting steel plate 41 .

15 is a view showing a rotary penetration rod provided with an injection material receiving portion.

As shown in FIG. 15 , a support steel plate 41 is provided on the outside of the front end of the rod body 4 by a predetermined height higher than the cutting arm 52 , and the cutting arm 52 is inside the rod body 4 . ) may be provided with an injection material accommodating portion 44 in which the injection material for supplying the injection material is accommodated.

In FIG. 15, the injection material accommodating part 44 is illustrated as being composed of a main accommodating part 44a and a hardening agent accommodating part 44b, but in some cases, among the main accommodating part 44a and the curing agent accommodating part 44b. Either one is provided in the injection material receiving portion 44, the other one can utilize the internal space of the rod body (4). In particular, when the proportion of the main body is 90%, only the injection material receiving part 44 for 10% of water is provided inside the front end rod body 4 and the main body is filled inside the front end rod body 4 .

When the injection material accommodating part 44 is separately composed of the main accommodating part 44a and the hardener accommodating part 44b, mixing the main agent and the hardener at the position where the inflow into the injection material supply path 521 of the cutting arm 52 starts An injection material mixing unit 45 may be provided for (FIG. 15).

In the case of using a delayed injection material, it is very simple to mix the main agent and hardener on the ground in advance and inject the injection material into the rod body 4 and then discharge the injection material by pressure such as pneumatic. 44) will play a role.

The support steel plate 41 is provided at a height higher than the cutting arm 52 so that the height difference between the cutting arm 52 and the support steel plate 41 becomes the height of the enlarged tip reinforcing part 6 .

When the diameter of the support steel plate 41 is 300 mm and the diameter of the enlarged tip reinforcing part 6 is 700 mm, assuming that the load distribution angle is about 27°, the support steel plate is provided at a position about 400 mm higher than the cutting arm. Just do it (300mm + 2 x 400mm x tan27° ≒ 700mm).

When the upper parts of the main accommodating part 44a and the hardener accommodating part 44b are opened, the mixed injection material is cut through the discharge part of the cutting arm 52 simply by supplying compressed air at a constant pressure through the swivel installed in the auger driver. It can be pressure-injected into the crushed ground. Even when the injection material accommodating part 44 is made of corrugated vinyl, the mixed injection material may be pressure-injected into the ground cut and crushed while the vinyl is contracted by compressed air. The rotary penetration rod 3 provided with the cutting arm 52 and the support steel plate 41, the injection material receiving part 44 and the injection material mixing part 45 provided in the spiral steel plate 51 can be configured as one product. have.

The rod body 4 may be provided with a fluid discharge part (not shown) for maintaining the hollow wall for discharging the fluid for maintaining the hollow wall generated in the process of recovering the rod to the ground.

The fluid discharge unit for maintaining the hollow wall may be configured to be able to be opened and closed.

If a stopper-type tip with a spring having a certain tension is simply attached to the tip of the rod body 4, the lower end of the rod body 4 is blocked during the downward rotational penetration, and the tip ends downward while recovering upward to the ground. As the lower part of the rod is opened, the fluid for maintaining the hollow wall, such as bentonite, which is filled in the rod in advance, automatically fills the hollow wall to prevent the collapse of the hollow wall. After that, lower the rod to a certain depth in the hole created during the rod rotation from the ground or lower it to the center of the expanded tip reinforcement (6) formed in the underground support ground. If the drilling operation is carried out in the inserted state, the pile (2) is accurately seated on the expanded tip reinforcement part (6) in the underground.

1: Ground 11: Soft ground
12: support ground
2: Pile 3: Rotating Penetration Rod
4: rod body 41: support steel plate
42: injection material supply hose 43: injection material inlet
44: injection material accommodating part 44a: subject accommodating part
44b: curing agent accommodating part 45: injection material mixing part
451: stirring blades
5: cutting part 51: spiral steel plate
511: discharge space 52: cutting arm
521: injection material supply path 522: discharge unit
523: protective cover 524: discharge part cover
53: eccentricity prevention part
6: Expanded tip reinforcement part

Claims (10)

It relates to a rotary penetration rod (3) provided with a cutting part (5) in the rod body (4) to form an enlarged tip reinforcement part (6) of the pile (2) in the underground support ground (12),
The cutting part 5 is located in the middle between the spiral steel plate 51 for rotation penetration and the spiral steel plate 51 provided on the outside of the rod body 4, or at the front end or rear end of the spiral steel plate 51 in the rotation direction, and the rotation penetration It is formed to protrude outward than the spiral steel plate 51 for use, and an injection material supply passage 521 is provided in the longitudinal direction, and on one side is communicated with the injection material supply passage 521 and is in communication with the crushed surrounding ground for injecting the injection material. A rotary penetration rod for forming an enlarged tip reinforcement part of a pile, characterized in that it consists of one or more cutting arms 52 on which the discharge part 522 is formed.
delete In claim 1,
The cutting arm (52) is a plate-shaped rotary penetration rod for forming an enlarged tip reinforcement part of the pile, characterized in that it has the same penetration angle as the spiral steel plate (51) for rotation penetration.
In claim 1,
The discharge part 522 is a rotary penetration rod for forming an enlarged tip reinforcement part of the pile, characterized in that the protective cover 523 is provided on the outside.
In claim 1,
The discharge part 522 is a rotary penetration rod for forming an enlarged tip reinforcement part of a pile, characterized in that it consists of three or more discharge holes whose discharge area increases toward the outside.
In claim 1,
The cutting arm (52) provided in the spiral steel plate (51) for rotation penetration is a rotary penetration rod for forming an enlarged tip reinforcement part of the pile, characterized in that it is provided near the tip of the rod body (4).
In claim 6,
A support steel plate 41 is provided at a height higher than the cutting arm 52 on the outside of the front end of the rod body 4, and the inside of the rod body 4 is for supplying an injection material to the cutting arm 52. The injection material supply hose 42 is provided to be connected to the injection material supply path 521 of the cutting arm 52 by the injection material inlet portion 43.
In claim 6,
A support steel plate 41 is provided at a height higher than the cutting arm 52 on the outside of the front end of the rod body 4, and the inside of the rod body 4 is for supplying an injection material to the cutting arm 52. A rotary penetration rod for forming an enlarged tip reinforcement portion of the pile, characterized in that the injection material receiving portion 44 in which the injection material is accommodated is provided.
In claim 6,
Reinforcement of the enlarged tip of the pile, characterized in that the rod body (4) is provided with a fluid discharge part for maintaining the hollow wall for discharging the fluid for maintaining the hollow wall generated in the process of recovering the rotary penetration rod (3) to the ground A rotating penetrating rod to form a part.
In claim 9,
A rotary penetration rod for forming an enlarged tip reinforcement part of the pile, characterized in that the opening and closing of the fluid discharge part for maintaining the hollow wall is possible.

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