KR101970992B1 - Non-displacement pile construction method therewith - Google Patents

Abstract

The present invention relates to a non-displacement pile and a pile press-in construction method using the same, which constructs a pile into the ground by pressing and rotating the same, thereby being not required for displacement operation by excavation, having excellent constructability and being possible to stably construct the pile. The non-displacement pile is constructed by using a pile body unit rotationally pressed into the ground so that a cavity part (S) filled with water (W) is formed at a boundary space (S1) between a pile outer circumferential surface and an excavation ground hole (A), a boundary space (S2) between an pile inner circumferential surface and the ground in the pile, and a space (S3) around a front end portion without using an augur device.

Description

Non-coating file and file pressing method using same {NON-DISPLACEMENT PILE CONSTRUCTION METHOD THEREWITH}

The present invention relates to a non-soil pile and a pile pressing method using the same. More specifically, the present invention relates to a non-pile file and a pile press-in method using the same, which do not need to apply the excavation work by excavating and rotating the pile in the ground, and have excellent workability and stable pile construction.

1A illustrates a method of constructing a pile in a conventional underground.

That is, after press-installed in the ground (20) while ground drilling a pile (50), such as a steel pipe that can accommodate the rotary drilling auger device 10 therein, and reaches a certain depth 40, the auger It can be seen that the device 10 is recovered, and the pile 50 is constructed in the ground 20 and 40 by injecting a filler 70 such as concrete into the constructed pile 50.

Figure 1b shows another conventional pile construction method.

That is, after the casing 60 is first inserted into the drilled hole to a predetermined depth 40, the pile 50 is inserted into the casing 60 in the casing 60, and then the drilled hole 50 is inserted into the casing 60. The casing 60 is drawn while filling the filler 70 in the space between the pile and the outer peripheral surface of the pile. It can be seen that the pile construction is completed by filling the grouting 60 to the final drilling hole height.

In this case, too, when constructing the casing 60, it can be seen that the work of discharging using an auger device (not shown) accommodated therein is required.

As a result, looking at the method of constructing the pile in the conventional underground, the auger device for inserting the casing or pile itself into the ground is absolutely necessary, which is why the excavation equipment such as power equipment for operating the auger is always premised. It can be seen that there is a problem that it is difficult to secure economic feasibility.

Republic of Korea Patent No. 10-1812463 (Invention name: Method of constructing a rotary press-type pile using a tip-extended steel pipe, published date: December 28, 2017) Republic of Korea Patent Publication No. 10-2018-0009196 (Invention name: Synthetic pile construction method using concrete filling, published date: January 26, 2018) Republic of Korea Patent No. 10-1144312 (Invention: Steel pipe pile tip expansion device and steel pipe pile construction method using the same, Publication Date: July 01, 2010)

Therefore, the present invention does not use an auger device, and forms an excavation bit at the tip of the pile so as to enable the construction of the pile, and the construction is carried out by rotating the pile so that no pile work is required according to the excavation of the ground, thereby simplifying the pile construction facility. The technical problem to solve the provision of the non-soil pile and the non-pile pile pressing method using the same that can ensure the efficiency and economic efficiency of pile construction.

In addition, according to the present invention, as the excavation bit is formed at the tip of the pile, the space portion is formed at the boundary with the ground, and thus, the rotary press-fitted pile may not be seated on the ground, thereby solving the problem of not sufficiently securing the tip bearing capacity. It is a technical problem to solve the provision of the non-soil pile and the non-pile pile press-fit method using the same by ensuring the frictional force of the pile and the ground more securely.

The non-soil pile of the present invention and the pile pressing method using the same for achieving the above object

Without using the auger device, the boundary space (S1) between the pile outer peripheral surface and the excavated ground hole (A), the boundary space (S2) between the pile inner peripheral surface and the ground inside the pile, and water (W) respectively Pile body portion that is rotationally press-fitted into the ground to form a cavity (S) to be filled; An excavation bit portion for being press-fitted into the ground while rotating the pile body portion and being integrally formed at the distal end portion of the pile body portion including a bit and a ring shoe; And a grouting part including a grouting pipe and a check valve as a grout filling pipe member installed in a straight form on the inner circumferential surface of the pile body, including a grouting pipe and a high pressure injected from the ground through a grouting pipe. In the process of discharging the water (W) pre-injected to the ground by the pressure by the grouting material is injected through the check valve located at the front end of the body portion, the grouting material is the boundary space (S1) between the pile outer peripheral surface and the excavation ground hole (A), pile inner peripheral surface Filled in the cavity (S) by the boundary space (S2) between the ground and the inside of the pile, and the space around the tip (S3) to be hardened to be integrated into the front end of the pile and ground, thereby securing end support and internal and external frictional force. The grouting portion grout filling pie is installed in a straight form on the inner peripheral surface of the pile body portion A grouting pipe and a check valve are included as a ping member, and the grouting protection part includes a grouting protection part so that the grouting part does not interfere with the rotational press. The grouting protection part includes a grouting pipe arranged to protrude on the inner circumferential surface of the pile body part. Pipe protection block which is a block mounted on the inner circumferential surface of the pile body around the grouting pipe so as not to be in direct contact with the ground; And a valve protection bit installed on the ring shoe around the check valve so that the bit is formed around the ring shoe so that the check valve is not subjected to resistance during rotational intrusion.

According to the non-pile file of the present invention and the pile press-fitting method using the same, the excavation facility for the excavation work according to the excavation of the ground is not required, so that the construction of the pile is possible quickly and economically.

In addition, according to the non-soil pile and the pile pressing method using the same according to the present invention, the cavity that occurs at the tip part, etc. during pile rotation pressing, that is, the boundary space (S1) between the pile outer peripheral surface and the excavation ground hole (A), the pile inner peripheral surface and the ground inside the pile The cavity (S), which is filled with water (W) in the boundary space (S2) and the space around the tip portion (S3), respectively, is filled with grouting material so that pile construction is possible to secure the tip support force and the pile friction force of the pile. do.

1A and 1B show a conventional pile construction diagram.
Figures 2a and 2b shows a perspective view of the non-soil pile configuration of the present invention.
Figures 3a, 3b and 3c shows a flow chart of the pile pressing method using a non-soil pile of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

[Non-contaminated file 100 of the present invention]

Figure 2a and Figure 2b shows a perspective view of the configuration of the pile 100 used in the non-soil pile pressing method of the present invention.

The pile 100, as shown in Figure 2a, including the pile body 110, excavation bit portion 120, grouting portion 140, grouting protection portion 150, grouting material 160 as the ground Constructed to be rotationally press-fitted in, but it is characterized in that it is rotatably pressed as it is without excavation and excavation of the ground inside the pile.

First, the pile body 110 may be referred to as a file commonly used, such as a hollow circular cross-section file, as shown in Figure 2a, and may be a steel pipe file, PHC file, and the like.

Since the pile body 110 is a cylindrical member having a predetermined thickness, the pile body 110 does not rotate in itself. In the present invention, the bit 121 is mounted on the tip end portion of the pile body 110 using the ring shoe 122, and the pile body 110 is pushed into the ground while the pile body 110 is rotated.

Therefore, the present invention requires only a facility for pile rotation pressing, and does not require a conventional auger device, and thus does not require a clay work by excavation because no auger device is used.

2A and 2B, the drilling bit portion 120 is to be pressed into the ground while rotating the pile body portion 110, including the pile 121 and the ring shoe 122 pile body portion 110 It is formed to be integrated to the front end of the.

The pile body 110 is a pile itself, so it is difficult to attach the bit 121 to the tip portion as it is, so that when the ring shoe fixed to the tip portion and the bit 121 previously integrated into the ring shoe 122 are used, the pile As the body 121 rotates, the bit 121 is also rotated, so that the rotary press-fit of the pile body 110 is possible.

Accordingly, the ring shoe 122 may be formed in a ring shape having a constant diameter, an extension length L, and a thickness T, such as a cross section of the tip end of the pile body 110, and may be integrated by welding or the like. Will be,

The bit 121 may use a grinding bit on an exposed surface of the ring shoe 122, and a plurality of bits 121 may be integrated along the surface.

The ring shoe 122 can also be used as a connecting means of the pile body portion 110, and in order to reduce the pressing resistance for rotational pressing, the advantage of being installed at the connecting portion except for the tip portion of the pile body portion 110. Will be.

Referring to FIG. 3A,

When the drilling bit 120 is integrated into the front end of the pile body 110, the pile body 110 is inserted into the ground and the boundary space (S1) between the outer peripheral surface of the pile 100 and the drilling ground hole (A),

Boundary space (S2) between the inner circumferential surface of the pile (100) and the ground inside the pile (100),

The tip peripheral space (S3) is left as an empty space so that the tip portion of the pile body 110 may not be seated on the ground at the design depth.

This is because the present invention is provided so that the bit 121 separately protrudes from the tip end of the pile body 110, and the bits 121 are formed to be spaced apart from each other.

Accordingly, the present invention provides a grouting material 160 to replace water while lubricating to reduce rotational indentation resistance and grouting material 160 is injected into the space occupied by water W in the state where water is first filled. Grouting unit 140 that can be injected is installed, for example, in the pile body 110.

Since the excavation by the auger device is not performed, the present invention is installed on the inner circumferential surface of the pile body 110 without using the inner space of the pile body 110 so that the resistance due to the rotational press is minimized.

The grouting part 140 is a grout filling pipe member installed in a straight shape on the inner circumferential surface of the pile body 110 as illustrated in FIGS. 2A and 2B, and includes a grouting pipe 141 and a check valve 142.

The grouting pipe 141 may be installed in close contact with the inner circumferential surface of the pile body 110, but in this case, the grouting pipe 141 may act as a rotational intrusion resistance factor due to the volume occupied, but may be overcome by installing a plurality of diameters so that the rotational intrusion resistance does not increase. do. Plastic pipe members may be used.

The check valve 142 is integrally connected to the front end of the grouting pipe 141 to enable the injection of water (W) or grouting material (160).

That is, when the water (W) or the grouting material 160 is injected into the grouting pipe 141 by the high pressure, the check valve 142 converts the pressure required for the spraying and controls the spraying direction through the nozzle. will be.

Accordingly, the head of the grouting pipe 141 is connected to the connection pipe 143 for injection of water (W) or grouting material 160 through the connection bracket 144, as shown in FIG. This is because the same grouting pipe 141 is used when injecting and injecting the grouting material 160, but the injecting means on the ground is different.

By using the connection pipe 143 for the water (W) or grouting material 160 separately, the same grouting pipe 141 can be used, and first, water (W) is injected and the grouting material 160 is timed. There is no fear of injecting otherwise and otherwise blocking.

At this time, the connection bracket 144 is set to be in contact with the outer peripheral surface of the grouting pipe 141 elastic rubber ring to enable the mounting and sealing of the connection pipe 143.

Since the grouting pipe 141 and the check valve 142 are those having a constant volume, they may interfere with rotational intrusion, but may be damaged due to contact with the ground while rotating.

Furthermore, the grouting protection part 150 is for protecting the grouting part 140.

The grouting protection unit 150 includes a pipe protection block 151 and a valve protection bit 152 as shown in FIGS. 2A and 2B.

The pipe protection block 151 is a pile body around the grouting pipe 141 so that the grouting pipe 141 disposed to protrude on the inner circumferential surface of the pile body 110 does not come into direct contact with the ground inside the pile body 110. Part 110 is a block mounted on the inner peripheral surface.

The grouting pipe 141 may be installed to surround a plurality of the plurality of grouting pipes, and the grouting pipe 141 may be installed at the front end of the grouting pipe 141 to which the check valve 142 is connected.

In this case, as shown in FIGS. 2A and 2B, the grouting unit 140 and the grouting protecting unit 150 may be arranged such that at least two or more are disposed in the pile 100.

Next, the valve protection bit 152 is to protect the check valve 142, but does not use a protective block surrounding the check valve, and additionally forms a bit around the ring shoe 122 so that the check valve 142 is press-fitted in rotation. The valve protection bit 152 may be installed on the ring shoe 122 around the check valve 142 so as not to be resisted.

The grouting material 160 is injected into the high pressure through the grouting pipe 141 from the ground through the connecting pipe 143 of the grouting part 140 to the check valve 142 located at the tip of the pile body portion as shown in FIG. By spraying.

The boundary space (S1) between the outer peripheral surface of the pile 100 and the excavation ground hole (A), the boundary space (S2) between the inner peripheral surface of the pile 100 and the ground inside the pile 100, Filled in the cavity (S) by the tip peripheral space (S3) and hardened to be integrated into the tip portion seating and ground of the pile 100, it is possible to secure the tip bearing force and the pile inner and outer peripheral surface friction force.

[Pile press method using the non-soil pile of the present invention]

Figures 3a, 3b and 3c is a flow chart of the construction method of the pile 100 used in the pile pressing method using the non-soil pile of the present invention.

Pressing the pile 100 according to the present invention, as described above, prepare a pile 100 including a pile body 110, excavation bit portion 120, grouting portion 140, grouting protection portion 150 And by using the grouting unit 140, the water (W) is first injected while rotating indentation.

At this time, since the soil is not excavated with the auger device through the pile body 110, the soil of the ground excavated by the construction of the pile 100 is not required, and the pile 100 is rotated by the pile 100. The final grouting material 160 is finally injected into the boundary space of the ground (G) and the pile 100 is integrated into the ground to be constructed.

Thus, as shown in FIG. 3A, the injection device including the pile 100 of the present invention described with reference to FIG. 2 and the water W and the grouting material 160 may be separately prepared.

The pile 100 is manufactured by including a pile body 110, an excavation bit portion 120, a grouting portion 140, a grouting protection portion 150, the excavation bit portion 120 is a pile body portion ( 110 is to be formed in the tip portion, it can be seen that the connecting pipe 143 is exposed to the head and is set vertically by using a rotary indentation device (not shown) at the position where the pile 100 should be constructed. .

At this time, the grouting unit 140 is preferably used in advance set on the inner side of the pile body 110, but can be constructed separately grouting unit 140, in this case the cap to protect the tip of the grouting pipe 141 It may be installed, while the cap is opened by the injection of water or grouting material may be sprayed sequentially water or grouting material.

The pile 100 set therein is rotatably press-fitted into the ground by rotating the excavation bit part 120 and the pile body part 110 in contact with the ground surface using a rotation indentation apparatus (not shown).

Next, as shown in FIG. 3b, the front end portion of the final pile 100 is rotationally pressed to reach the planned depth G2, and if necessary, a plurality of piles 100 using the ring shoe 122 of the drilling bit 120. ) Is installed while connecting, and water (W) is injected into the front end portion using the grouting part 140 to reduce the rotational indentation resistance.

The water W injected therein is a boundary space S1 between the outer circumferential surface of the pile 100 and the excavation ground hole A, and a boundary space S2 between the inner circumferential surface of the pile 100 and the ground inside the pile 100 is formed. The excavation bit portion 120 protrudes downward to serve as a lubricating action while being injected into the peripheral space around the tip portion S3, thereby maintaining a space in which the grouting material 160 is injected.

Accordingly, when the pile 100 is rotationally pressed, the boundary space S1 between the outer circumferential surface of the pile 100 and the excavation ground hole A, the boundary space S2 between the inner circumferential surface of the pile 100 and the ground inside the pile 100, and around the tip portion It can be seen that the cavity S filled with water W is formed in the space S3, respectively.

Next, as shown in FIG. 3c, the grouting material 160 is injected into the grouting part 140 by replacing the water W through the connection pipe 143. Accordingly, the water (W) is discharged to the ground through the cavity (S) from the tip by the grouting material 160, which is injected under high pressure, and the ground (G) when the final grouting material 160 is cured to replace the water (W) The pile 100 is seated.

In particular, when the space around the tip portion (S3) of the pile 100 is formed, it may occur that the pile body portion 100 is not seated in the ground, so that the grouting material 160 serves to fill the pile 100, the pile 100. It is practically possible to secure the tip bearing capacity of and since the ground is not disposed, the equipment is simplified by not using the auger device.

The grouting material 160 is hardened in the boundary space (S1) between the outer peripheral surface and the ground of the pile 100, the inner peripheral surface and the ground space (S2) between the ground inside the pile 100 and the inner peripheral surface of the pile body 110 It is possible to secure the frictional force on the outer circumferential surface is very advantageous for securing the bearing capacity due to the front end support force and the peripheral frictional force of the pile 100.

The foregoing description of the present invention is intended for illustration, and it will be understood by those skilled in the art that the present invention may be easily modified in other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are exemplary in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

100: file 110: file body
120: drilling bit portion 121: bit
122: ring shoe 140: grouting portion
141: grouting pipe 142: check valve
143: connecting pipe 144: connecting bracket
150: grouting protection unit 151: pipe protection block
152: valve protection bit 160: grouting material
A: Excavation ground hole G: Ground
S1: boundary space between pile outer circumference and excavation ground hole
S2: boundary space between the inner circumference of the pile and the ground inside the pile
S3: Space around the tip G1: Planned depth

Claims (6)

Without using the auger device, the boundary space (S1) between the outer peripheral surface of the pile (100) and the excavation ground hole (A), the boundary space (S2) between the inner peripheral surface of the pile (100) and the ground inside the pile (100), the space around the tip end ( Pile body portion 110 is rotatably pressed into the ground so that the cavity (S) is filled in each of the water (W) in S3);
Excavation bit portion 120 to be pressed into the ground while rotating the pile body portion 110, including a bit 121 and the ring shoe 122 is formed to be integrated to the front end of the pile body portion 110; And
Including; Grouting portion 140, which is a grout filling pipe member installed in a straight form on the pile body portion 110,
In the process of discharging the water (W) pre-filled through the grouting portion 140 to the ground, the grouting material 160 is the boundary space (S1), pile between the outer peripheral surface of the pile 100 and the excavation ground hole (A) (100) Filled in the cavity (S) by the boundary space (S2) between the inner circumferential surface and the ground inside the pile (100), the space around the tip portion (S3) and hardened so as to be integrated into the tip seating and ground of the pile (100). It is possible to secure bearing capacity and friction force inside and outside the pile,
The grouting part 140 is a grout filling pipe member which is installed in a straight shape on the inner circumferential surface of the pile body 110 to include a grouting pipe 141 and a check valve 142, and the grouting part 140 rotates. The grouting protection part 150 is included so as not to interfere with the indentation, and the grouting protection part 150 has a grouting pipe 141 disposed to protrude on the inner circumferential surface of the pile body part 110 in the pile body part 110. A pipe protection block 151 which is a block mounted on the inner circumferential surface of the pile body 110 around the grouting pipe 141 so as not to be in direct contact with the ground; And a valve protection bit 152 installed on the ring shoe 122 around the check valve 142 so as to form a bit around the ring shoe 122 so that the check valve 142 is not resisted during rotational intrusion. . delete The method of claim 1,
In addition to the grouting unit 140 to install a cap to protect the front end of the grouting pipe 141, the cap is opened by the injection of water or grouting material that can be sequentially sprayed with water or grouting material . (a) Excavation bit portion 120 which is formed to be integrated into the front end portion of the pile body portion 110, including the bit 121 and the ring shoe 122 to be pressed into the ground while rotating the pile body portion 110 Having a pile 100 having a;
(b) Without using an auger device, the pile 100 is bounded by the boundary space S1 between the outer peripheral surface of the pile 100 and the excavation ground hole A, the boundary between the inner peripheral surface of the pile 100 and the ground inside the pile 100. Rotatably press-fitting the ground such that a cavity S filled with water W is formed in the space S2 and the space around the tip portion S3; And
(c) the grouting material 160 at a high pressure through the grouting pipe 141 on the ground through the connection pipe 143 connected to the grouting pipe 141 of the grouting part 140 installed on the pile body 110; Including; Including;
In the step (c), the grouting material 160 is injected by the distal end of the grouting part 140, so that the grouting material 160 is pile 100 in the process of discharging the water (W) injected in advance to the ground. ) In the cavity S by the boundary space S1 between the outer circumferential surface and the excavated ground hole A, the boundary space S2 between the inner circumferential surface of the pile 100 and the ground inside the pile 100, and the space around the tip end S3. Filled and hardened to be integrated in the tip end seating and ground of the pile 100, it is possible to secure the tip bearing force and the friction force in the inner and outer peripheral surfaces,
The head of the grouting pipe 141 of step (c) is connected to the connection pipe 143 for injecting water (W) or grouting material 160 through the connection bracket 144, the connection pipe 143 By using the connection pipe 143 for the water (W) or grouting material 160 separately to enable the same grouting pipe 141, the connection bracket 144 is a grouting rubber ring with a rubber ring ( 141) Pile pressing method using a non-soil pile to enable the mounting and sealing of the connecting pipe 143 by setting to contact the outer peripheral surface. delete The method of claim 4, wherein
The grouting part 140 of step (c) may be provided with a cap that protects the tip of the grouting pipe 141 and may sequentially spray water or grouting material while the cap is opened by injecting water or grouting material. Pile press method using uncoated pile

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