KR20150131911A - Self-extending piles and construction method thereof - Google Patents

Abstract

The present invention relates to a self-expansion pile and a construction method thereof, capable of expansion cutting and forming a pile expansion unit with the pile itself without an expansion drill, and reliably increasing a support force by forming a desired size of the pile expansion unit in not only a soil layer but also a solid rock layer. The self-expansion pile comprises: a pile main body installed underground; an expansion unit expanding a diameter while rotating with the pile main body by being connected to a lower part of the pile main body; and a pressing body to expand a diameter of the expansion unit. The expansion unit comprises: a cylindrical expansion unit main body having a pressing body storage space inside, a wing unit storage space formed along an outer circumference on a side, and a plurality of guide holes connected to the pressing body storage space and the wing unit storage space; and an expanding unit comprising an arc-shaped wing unit stored in the wing unit storage space having a cutting tip connected outside, and a pressing unit protruding from a rear end of the wing unit and penetrating the guide hole in order for the end to be located in the pressing body storage space. The pressing body presses the end of the pressing unit in the pressing body storage space, and an expansion body slides to the outside of the expansion unit main body in a radial direction; thus expanding the expansion unit.

Description

SELF-EXTENDING PILES AND CONSTRUCTION METHOD THEREOF FIELD OF THE INVENTION [0001]

The present invention relates to a self-piercing pile for use in the construction of a building or for fixing a structure, and more particularly, to a method of constructing a pile of a pile, In addition, the present invention relates to a self-diameter pile and a method of constructing the self-diameter pile, which can reliably increase the supporting force by forming a pile enlargement portion having a desired size even in a hard rock layer.

Generally, piles installed in the ground for foundation or fixation of various construction and civil structures such as ground structures and offshore structures are designed to receive compressive force mainly at the tip. In order to efficiently use waste piles efficiently from the material side, It is necessary to expand the periphery of the tip of the pile to increase the allowable supporting force.

In the past, there have been many methods of expanding the tip of a pile, and there have been cases where an irregular enlarged portion at the tip of the pile has been formed which is difficult to predict in design of the soft layer.

In most cases where the tip of the pile is enlarged, the pile should be inserted into the rock layer over the weathering hole. Therefore, the vertical piercing to the rock layer is completed with the straight piercing drill and the process of drilling the end of the piercing hole with a separate piercing drill is required. After that, the residual slime at the end of the hole is cleanly removed, the air hole of the diameter hole is stabilized, and concrete is poured into the installation space of the pile enlargement part. Through such a process, an enlarged concrete reinforcing portion is formed at the tip of the pile inserted into the perforation hole.

However, in the above-described conventional technique, the amount of the used equipment is increased, the amount of the perforation is increased more than necessary, and it is difficult to prevent the air hole of the diameter hole from loosening or collapsing during the perforating operation for expanding the distal end.

Furthermore, since the slurry and the groundwater are naturally mixed in the clearance space where the pile enlargement part is to be formed, the quality of the concrete paved here is also difficult to guarantee the level required by the pile enlargement part.

According to another example of the prior art, a wedge provided at the distal end of a pile body may enlarge the extension body radially to form a pile enlarged portion (Japanese Patent Application Laid-Open No. 10-2013-0002731). However, since there is a gap between the adjacent extensions after the completion of the expansion of the hard extender, the above-described technique has a disadvantage that the support area of the enlarged pile is limited because it is difficult to form a continuous pile enlargement part. In addition, even if concrete is poured into the pile enlarging portion, the slime is inserted between the expanding bodies, so that it is difficult for the pile body and the expanding body to be integrated. As a result, when the load is applied to the pile, the expansion body becomes loose, and the settlement amount of the pile increases when the load is applied after the completion of the structure. Also, even if pressure is applied to the concrete after forming the pile enlargement part, the concrete leaks through the gap between the expansion bodies and leaks into the gap between the outer peripheral surface of the pile body and the perforation hole.

In addition, while the expander is expanded by the wedge action, the expander is radially expanded as it is lower than the tip of the pile body, and resists the axial force about the area of either the straight hole portion of the lower portion of the pile body or the pile enlargement portion. It was difficult to increase the allowable load.

Particularly, there is a limitation in applying to a weak ground such as a structure in which a ground is cut by rotation of an expander having a cutting tip, but a form in which the expander is radially press-fitted into the ground or is of a type only.

In order to solve the above problems, the present invention provides a self-diameter pile having a maximum pile enlargement size, which is designed not only in the soil layer but also in a hard rock layer to improve the permissible supporting force of the pile installed in the ground, Method.

The present invention provides a self-diameter pile having a diameter cutting function and capable of supporting a diameter hole at the same time as the diameter of the pile, and a method of constructing the pile.

The present invention provides a self-diameter pile having excellent economical efficiency and a method of constructing the self-diameter pile, which is constructed of a rigid and inexpensive material such as high-strength concrete.

The present invention provides a self-diameter pile capable of forming a pile enlargement part in any ground layer and a method of constructing the self-pile pile, in which the expansion body plays the same role as a drill bit and can be magnified even in a hard rock.

The present invention relates to a pile of a pile having a self-diameter pile capable of forming a pile enlarged portion capable of rapidly cutting a large diameter at a high pressure without breakage of the pile and constituting a pressing force for radially expanding the pile expanding portion to a grout pressure, And to provide a construction method.

According to a preferred embodiment of the present invention, there is provided a self-diameter pile comprising a pile body installed in the ground, a piercing hole coupled to the bottom of the pile body and rotating while expanding its diameter, and a pressing body for expanding the diameter of the piercing hole, And a plurality of guide holes are formed on the side surface to form a wing portion accommodating space along the outer circumferential surface and to communicate with the pressurizing member accommodating space and the wing portion accommodating space, A mouthpiece body; And an expanding body formed of an arc-shaped wing portion accommodated in the wing portion receiving space and having a cutting tip coupled to the outer side thereof, and a pressing portion protruding from the rear end of the wing portion and inserted into the guide hole; Wherein the pressing body pushes the end portion of the pressing portion in the guide hole direction in the pressing body receiving space and the expanding body is slid radially outwardly from the main body to enlarge the diameter hole.

According to another preferred embodiment of the present invention, the end of the wing portion of the expander is positioned in the pressurizing container storage space, and the lower end of the presser body is conical, and the upper portion of the pressurizing container storage space is opened, Wherein the expansion body is slid to the outside by moving the pressing body downward through the open space of the body housing space and pressing the end of the pressing portion of the expanding body.

According to another preferred embodiment of the present invention, a side surface of the pressing body further includes a plurality of horizontal auxiliary pressing bodies which are slidably protruded to the outside of the pressing body to further push the pressing end of the extending body to push the pressing body. Provide a pile.

According to another preferred embodiment of the present invention, the pressure body is a fluid, and a fluid pressure supply passage is formed in the upper portion of the pressurizing body storage space of the quadrangular prism body so as to communicate with the pressurizing body storage space, And the expansion body is slid to the outside by feeding the compressed body into the pressurizing body storage space and pressing the end of the pressurizing portion of the expander by the pressure of the fluid.

According to another preferred embodiment of the present invention, at least one of a side surface of the wing portion and a side surface of the guide hole is provided with a fluid transfer passage through which the fluid is discharged to the outside.

According to another preferred embodiment of the present invention, the extension body is formed with a predetermined length along the extension direction of the extension body, and the extension length of the wing portion is inserted into the engagement groove at the upper portion of the blade storage space, Wherein a limiting stopper is formed to protrude.

According to another preferred embodiment of the present invention, when the expander is protruded outwardly from the upper portion or the lower portion between the wings of the adjacent expander, the widened portion moves to the outside by the movement of the wing portion, And an expander is additionally provided on the pile.

According to another preferred embodiment of the present invention, the pile body is a concrete pile having a hollow in the vertical direction inside thereof, and the pore hole is formed integrally with the bottom of the pile body by concrete.

According to another preferred embodiment of the present invention, there is provided a self-piercing pile having an outer diameter larger than a pile body.

 According to another preferred embodiment of the present invention, a reinforcing plate is coupled to an upper surface of the wing portion receiving space and an inner surface of the guide hole.

According to another preferred embodiment of the present invention, there is provided a self-diameter pile, wherein a slime inflow point having a sharp bottom is detachably coupled to a lower portion of the main body by pressurization of a pressurizing body.

According to another preferred embodiment of the present invention, there is provided a self-pierced pile, which is provided at one side of the upper portion of the pile body, and which is protruded outside the pile body.

According to another preferred embodiment of the present invention, there is provided a self-piercing pile, wherein the piercing hole is formed of a high-strength concrete rather than a pile main body.

According to another preferred embodiment of the present invention, there is provided a self-piercing pile characterized in that a mesh member is provided between the pile body and the piercing hole.

According to another preferred embodiment of the present invention, a support groove is formed along the circumference on the outer circumferential surface on the upper side of the wing portion receiving space of the hollow body.

According to a preferred embodiment of the present invention, there is provided a method of constructing a self-diameter pile, comprising the steps of: (a) forming a perforation hole in a ground; (b) inserting a self-piercing pile, which is coupled to the bottom of the pile main body, into the perforation hole; And (c) pressing the end of the pressing portion by inserting a pressing body into the pressing body receiving space while rotating the probe, so that the expanding body expands outside the probe body while cutting the ground; The present invention provides a method of constructing a self-diameter pile.

According to a preferred embodiment of the present invention, there is provided a method of constructing a piercing pile, comprising the steps of: (a) forming a perforation hole in a ground; (b) inserting a magnifying glass into the lower portion of the perforation hole; (c) inserting a pressurizing member into the pressurizing member storage space while pressing the end of the pressurizing member while rotating the seal member, thereby expanding the expanding member to the outside of the seal member while cutting the ground; And (d) forming concrete pouring holes by pouring concrete into the open top of the pour point; The present invention provides a method of constructing a self-diameter pile.

According to a preferred embodiment of the present invention, there is provided a method of constructing a pile with a diameter, the method comprising the steps of: (a) inserting a self-piercing pile coupled to the bottom of the pile body by type, indentation or rotation penetration; (b) pressing the end of the pressing portion by inserting the pressing body into the pressing body receiving space while rotating the centering rod, so that the extending body expands outside the center body while cutting the ground; The present invention provides a method of constructing a self-diameter pile.

The present invention has the following effects.

First, since the extension with rotary cutting tip serves as a drill bit, the pile enlargement part can be formed in various strata from general to hard rock layer, so that the allowable bearing capacity of the pile can be greatly increased. Therefore, not only the pile construction cost of buildings and bridges can be reduced, but also the pile application range can be extended, for example, the pile base can be treated as a foundation or the pile base can be treated as a foundation.

Second, since the pile enlargement part continuous to the magnifying glass hole is formed immediately during the minutia cutting operation with the rotary cutting tip mounted on the enlarging device of the magnifying orifice, there is no fear that the pore wall of the magnifying hole is relaxed or collapsed during the magnifying operation, It is possible to form a continuous pile enlargement part having the largest area, so that the maximum pile holding force can be obtained.

Third, the cutting tip provides a pile enlargement section with precisely designed dimensions without excessive cutting, so the bearing capacity and pullout resistance can be greatly increased by the minimum amount of cutting work and the minimum amount of expansion.

Fourth, the material cost can be reduced if the hollow hole that cuts the perforated hole is made of the same cheap material as concrete.

Fifth, in the case where the wings of the adjacent extensions are made to contact with each other or the sub-expander that closes the space between the adjacent wings is further provided, the slime does not flow between the extensions, And the settlement amount of the pile does not increase even if the load is applied to the structure.

Sixth, in the case where the horizontal auxiliary pressing body is provided on the side surface of the pressing body, it is possible to further increase the allowable supporting force of the pile by increasing the extension range of the extension body.

Seventh, the hardenable fluid that is completely filled inside the mouth cavity integrates all the members of the mouth to improve the durability of all members constituting the mouth.

Eighth, continuous pile enlargement can be formed not only in the established pile but also in the casting piles in the field, thus enabling safe and economical construction.

1 is a perspective view of a self-diameter pile of the present invention.
2 is a cross-sectional perspective view of the distal end body.
3 is a perspective view of an extension.
4 is a cross-sectional perspective view of the self-diameter pile of the present invention having a horizontal auxiliary presser.
5 is a cross-sectional perspective view of a pressurizing body showing the operation of the horizontal auxiliary pressing body.
6 is a cross-sectional view of the self-diameter pile of the present invention showing the expansion process of the extension.
7 is a cross-sectional perspective view showing another embodiment of the pressing body.
8 is a sectional view of the self-diameter pile of the present invention showing the recovery process of the pressurized body.
9 is a cross-sectional perspective view showing an embodiment of a self-diameter pile of the present invention corresponding to the case where the pressurizing body is a fluid.
FIG. 10 is a perspective view showing an embodiment of a magnifying device provided with a secondary expander; FIG.
11 is a cross-sectional perspective view of a self-diameter pile of the present invention having a pile body with a hollow therein.
12 is a cross-sectional perspective view of the self-diameter pile of the present invention having a reinforcing plate.
13 is a perspective view of a reinforcing plate;
14 is a perspective view showing a reinforcing plate to which a filler is attached to a lower portion;
Fig. 15 (a) is a perspective view of the self-diameter pile according to the present invention in which adjoining expanders are overlapped with each other, and Fig. 15 (b) is a perspective view of the self-diameter pile of the present invention formed on a surface corresponding to the guide projection and the guide groove.
16 is a perspective view of the self-diameter pile of the present invention having a punch-in area.
17 is a perspective view of the self-diameter pile of the present invention having a mesh member.
18 is a cross-sectional perspective view of the self-diameter pile of the present invention provided with the attaching / detaching member.
19 is a view showing a stepwise process of a manufacturing method of a self-diameter pile according to the present invention in the case of pre-fabricating a punch.
20 and 21 are cross-sectional perspective views of the self-diameter pile of the present invention having a coupling portion.
22 is a view showing the self-diameter pile of the present invention having a support groove;
23 is a cross-sectional view showing an embodiment of the present invention for rotating a magnifying glass.

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

FIG. 1 is a perspective view of a self-diameter pile of the present invention, FIG. 2 is a cross-sectional perspective view of a quadrangular prism body, and FIG.

As shown in FIGS. 1 (a) to 1 (b), the self-diameter pile of the present invention is coupled to the lower part of the pile main body 1 installed in the ground, And a pressing body 3 for expanding the diameter of the mouth piece 2 and the mouth piece 2.

The self-diameter pile of the present invention can be widely applied to a foundation pile such as a steel pipe pile, a PHC pile, an H-shaped pile, a synthetic pile, a compound pile, and a cast-in-place pile.

The piercing mouth 2 is mounted at the tip of the pile body 1, so that it is possible to secure an additional supporting force in addition to the supporting force of the pile body 1 through the pile enlarging portion formed by the piercing mouth 2.

The piercing mouthpiece 2 may be integrally formed with the pile body 1 or may be constructed so as to integrally move with the pile body 1 after the piercing mouthpiece 2 is manufactured.

In the latter case, the piercing body 2 is separated from the pile body 1 to form a pile enlarged portion independently of the piercing hole, and then the pile or the casting pile can be joined to the upper portion of the piercing mouth 2 . In this case, when the pile body 1 is coupled to prevent the relative rotation between the piercing body 1 and the piercing mouth 2, the piercing body 2 can be rotated according to the rotation of the pile body 1, And the hollow shaft 2 can be rotated relative to each other, only the hollow shaft 2 can be rotated separately from the pile body 1 to cut the ground.

The mouthpiece 2 is composed of a mouthpiece body 21 and an extension body 22.

2 (a) to 2 (b), the pressurizing body accommodating space 211 is formed therein. The wing body accommodating space 212 is formed along the outer circumferential surface of the pressurizing body accommodating space 211, And a plurality of guide holes 213 are formed so as to communicate with the pressurizing-body accommodating space 211 and the wing-portion accommodating space 212, and have a cylindrical shape.

The porous body 21 can be manufactured by curing or injecting various materials such as synthetic resin and metal, but most preferably, it can be made of cement grout, mortar, concrete, or the like.

The quadrangular pyramid body 21 can be constructed as a single integral body. In this case, weak portions due to member joining do not occur, which is advantageous for load transmission.

When the compact body 21 is made of concrete using a mold frame, cost and manufacturing time can be shortened. Particularly, it is possible to increase the toughness of the main surface member by disposing a reinforcing material such as reinforcing steel in the interior of the concrete or dispersing the fiber reinforcing material evenly.

The portion of the quadrangular pyramid main body 21 located above and below the wing portion accommodating space 212 guides the extending direction of the expander 22 and transfers the upper load to the lower ground of the pile enlarging portion.

3, the extension body 22 is housed in the wing portion accommodating space 212 and has an arc-shaped wing portion 221 having a cutting tip T coupled to the outer side thereof, And a pressing part 222 protruding from a rear end of the guide part 221 and inserted into the guide hole 213.

The extension body 22 is provided so that the wing portion 221 contacts the wing portion 221 of the adjacent extension body 22 while being housed in the wing portion accommodation space 212, (a), the wings 221 of the adjacent extensions 22 may overlap each other.

3 (a)) or may be formed into a plate shape using a steel material (FIG. 3 (b)).

The inclined surface can be formed at the rear end of the extension body 22 in a shape corresponding to the lower end of the pressing body 3.

1 (b), the pressing body 3 presses the end portion of the pressing portion 222 in the pressing body accommodating space 211 in the direction of the guide hole 213, so that the extending body 22 is radially So that the piercing mouth 2 is enlarged to form a pile enlarged portion on the ground.

The expansion body 22 serves as a permanent support member of the pile enlargement unit in an enlarged state when the construction of the pile including the pile enlargement unit is completed.

The pressing body 3 can be formed in a cylindrical shape whose lower end is conical. In this case, the wing portion 221 of the expanding body 22 is positioned such that the end portion thereof is located in the pressurizing body accommodating space 211 and the upper portion of the pressurizing body accommodating space 211 is opened The pressing body 3 is moved downward through the open space of the pressing body accommodating space 211 to press the end of the pressing portion 222 of the expanding body 22 so that the expanding body 22 is slid to the outside Can be configured.

At this time, the mouthpiece body 21 can be configured to open the lower portion of the pressurizing-body accommodating space 211 as shown in Fig. 2A or to close it with the lower member 29 as shown in Fig. 2B .

In particular, when the lower portion of the pressurizing-body accommodating space 211 is closed, a groove can be formed so that the lower end of the pressing body 3 can be seated on the upper part of the lower member 29, It is preferable to form the buoyancy prevention hole 291 into which the groundwater flows so as not to interfere with the insertion of the pile.

It is preferable that the buoyancy prevention holes 291 are formed in the lateral direction of the lower member 29 in order to prevent clogging of the pile driver.

As shown in FIG. 2 (a), an automatic supply line 217 for injecting a curable bonding material into the dispenser 2 can be formed on the dispenser main body 21.

By using the automatic supply line 217, it is possible to supply the joint filler to an empty space generated as the expanding body 22 radially expands while inserting the pile into the perforation hole.

FIG. 4 is a cross-sectional perspective view of the self-diameter pile of the present invention having a horizontal auxiliary pressing body, FIG. 5 is a sectional perspective view of the pressing body showing the operation of the horizontal auxiliary pressing body, Sectional view of the self-diameter pile according to the present invention.

4 to 6, a side surface of the pressing body 3 is slid to protrude to the outside of the pressing body 3 so as to further push and push the end of the pressing portion 222 of the extending body 22 A plurality of horizontal auxiliary pressing bodies 33 may be further provided.

The horizontal auxiliary pressing body 33 further enlarges the extension range of the extension body 22.

6 (a)), when the horizontal auxiliary pressing body 33 is positioned at the same height as the extension body 22 (see FIG. 6 (FIG. 6B). Thereafter, the horizontal auxiliary pressing body 33 presses the extension body 22 to further expand the extension range of the extension body 22 (FIG. 6C).

5 (a) to 5 (b), a through hole 31 extending to the upper surface of the pressing member 3 is formed in the pressing member 3, A plurality of inlet / outlet holes 32 in which the horizontal auxiliary pressing bodies 33 are housed are arranged in the horizontal direction so as to communicate with the through holes 31 so that the end portions of the horizontal auxiliary pressing bodies 33 are positioned within the straight holes 31 A vertical auxiliary pressing body 34 provided so as to be vertically movable in the vertical hole 31 presses the end portion of the horizontal auxiliary pressing body 33 so that the horizontal auxiliary pressing body 33 is moved to the outside of the pressing body 3 So that the end of the pressing portion 222 of the expanding body 22 can be pressed.

At this time, inclined portions 331 and 332 may be formed on the upper and lower ends of the outer side of the horizontal auxiliary pressing body 33.

Here, the lower inclined portion 332 is a portion that allows the horizontal auxiliary pressing body 33 to be pressed more easily. The upper inclined portion 331 is engaged with the upper end of the guide hole 213 of the scooping main body 21 so that the horizontal auxiliary pressing body 33 is slid back to the entry / exit hole 32 when the pressing body 3 is recovered. In other words, the horizontal auxiliary pressing body 33 is housed in the entry / exit hole 32 so as not to be caught by the guide hole 213 when the pressing body 3 is recovered.

The embodiment shown in FIG. 4 (b) is an example in which the punch body 2 is pulled under the pile body 1 and the steel wire ST to introduce a prestress, and the punch body 2 ). ≪ / RTI > In this case, in addition to the steel wire ST, it is also possible to join with a steel bar.

FIG. 7 is a cross-sectional perspective view showing another embodiment of the pressing body, and FIG. 8 is a sectional view of the self-diameter pile of the present invention showing the recovery process of the pressing body.

7, a through hole 35 through which the stopper 36 is inserted is formed on one side of the upper surface of the pressing body 3, and a through hole 35 is formed in the side surface of the vertical auxiliary pressing body 34 A locking hole insertion groove 341 in which the end of the locking hole 36 is inserted and locked is formed in a vertical direction so that the entire pressing body 3 can be lifted when the vertical auxiliary pressing body 34 is lifted.

8 (a)), when the vertical auxiliary pressing body 34 is lifted up, the horizontal auxiliary pressing body 33 returns to its original position (FIG. 8 (FIG. 8 (b) to FIG. 8 (c)), and then the stopper 36 is hooked on the lower end of the stopper insertion groove 341 to lift the entire pressure body 3 (FIG.

Accordingly, the pressing body 3 can be easily recovered.

9 is a cross-sectional perspective view showing an embodiment of a self-diameter pile of the present invention corresponding to the case where the pressurizing body is a fluid.

9, the pressurizing body 3 is a fluid, and a fluid pressure supply passage 214 is formed above the pressurizing body accommodating space 211 of the main body 21, So that the fluid is supplied to the pressure accommodating space 211 through the fluid pressure supplying passage 214 and the end of the pressing portion 222 of the expanding body 22 is pressed by the pressure of the fluid, (22) is slid to the outside.

The fluid may be water, air, or mortar.

Particularly, when the fluid is a mortar, the fluid is hardened in the interior and integrated with the quenching mouth 2.

In the embodiment of FIG. 9, the expanding body 22 radially expands due to the fluid pressure to form a pile enlarged portion together with a minutiae cutting along the ground, and a joint filler is tightly filled around the pile enlargement portion, As the filler material is injected at a high pressure, the ground can be firmly consolidated to increase the density.

In addition, a continuous pile enlargement is formed to remove the clearance that the filler material can escape from the lower ground. Then, the filler material is filled in the lower ground, and the filler material (3) To increase the density of the lower ground.

At least one of a side surface of the wing portion 221 and a side surface of the guide hole 213 may be formed with a fluid movement path G through which the fluid is discharged to the outside.

The fluid for slime discharge can be rapidly discharged to the outside through the fluid transfer passage (G).

The fluid transfer passage G also serves as a passage for the joint filler when the expandable body 22 is pushed out by using a curable joint filler.

The upper surface of the extension body 22 is formed with an engagement groove 223 having a predetermined length along the extending direction of the extension body 22 and is inserted into the engagement groove 223 at the upper portion of the blade accommodation space 212. And a stopper 215 for limiting the extension length of the wing portion 221 may be protruded.

In the case of the pressing body 3 whose lower end is the cone described with reference to Fig. 1, the expansion distance of the expanding body 22 is determined by the diameter of the pressing body 3. [ However, when the expander 22 is pressed by the pressure of the fluid as in the embodiment of FIG. 9, the maximum extension distance of the expander 22 can not be adjusted, so that when the expander 22 is detached according to the ground conditions May occur.

Therefore, a stopper 215 is provided at an upper portion of the wing portion accommodating space 212 to adjust or restrict the extension distance of the extension body 22.

FIG. 10 is a perspective view showing an embodiment of a magnifying lens provided with a secondary expander. FIG.

As shown in FIG. 10, when the extension body 22 is protruded to the outside, the wing portion 221 is moved upward or downward between the wing portions 221 of the adjacent extension body 22, (23) closing the space between adjacent wings (221).

The secondary expansion body 23 is disposed between adjacent expansion bodies 22 and is disposed so that both sides thereof overlap with a part of the expansion body 22. The extension body 22 is composed of a wing portion 221 and a pressing portion 222 while the secondary extension body 23 is composed of only a wing portion without a pressing portion.

As a result, when the pressing portion 222 of the expanding body 22 is pressed and the wing portion 221 is protruded to the outside, the auxiliary expanding body 23 protrudes outwardly as the expanding body 22 moves.

In this case, it is possible to reduce the number of the guide holes 213 of the distal end main body 21 by the number of the secondary extensions 23, and the configuration of the distal end main body 21 is simple. Further, since only the pressing portion 222 of the expanding body 22 needs to be pressed, the pressing is easy.

10 (b) to 10 (c), the fitting groove 224 is formed on the upper surface of the extension body 22, the fitting projection 231 is formed on the lower surface of the auxiliary extension body 23, In the case of forming the fitting portion on the upper surface of the auxiliary extension 22 and the fitting portion on the lower surface of the auxiliary extension 23, The fitting projections engage with each other.

Therefore, the secondary expansion body 23 protrudes outwardly in accordance with the expansion of the expansion body 22, so that a continuous expansion body can be formed on a plane, so that a large external force acting on the pile enlargement part can be supported. In addition, since there is no leakage gap due to the continuous pile enlarged portion, the hardenable joint filler that is filled in the empty space on the back surface of the expanding body 22 due to radial expansion of the expander 22 is very dense It is possible to prevent the settlement of the pile.

11 is a cross-sectional perspective view of a self-diameter pile of the present invention having a pile body with a hollow therein.

11, the pile body 1 is a concrete pile having a hollow 11 formed therein in a vertical direction, and the pore hole 2 is integrally formed with the bottom of the pile body 1 as concrete .

The piercing body 2 may be separately formed from the pile body 1 and connected to the lower portion of the pile body 1. However, 2 can be integrally formed and the piercing mouth 2 can be integrally formed with the pile body 1 together with concrete.

In particular, it is easier to integrally form the concrete foundation pile 2 and the concrete foundation pile without using the steel wire.

At this time, the pressurizing-body accommodating space 211 of the piercing main body 21 is integrally formed so as to communicate with the hollow 11 of the pile body 1.

The hollow 11 can serve as an entry passage for the cylindrical pressing body 3 whose tip is conical or fluid pressurizing body 3.

In addition, the mouthpiece 2 may have a larger outer diameter than the pile body 1.

In the case of a concrete pile, the diameter of the outer diameter and the inner diameter is determined, and the thickness is somewhat insufficient for accommodating the expansion body 22 only by the thickness of the pile.

Therefore, it is preferable to make the outer diameter of the mouthpiece 2 larger so that the expandable body 22 is sufficiently housed in the wing-portion accommodating space 212.

FIG. 12 is a perspective view of a self-diameter pile of the present invention having a reinforcing plate, FIG. 13 is a perspective view of the reinforcing plate, and FIG. 14 is a perspective view showing a reinforcing plate to which a filler is attached.

12 to 14, the reinforcing plate 24 can be coupled to the upper surface of the wing portion accommodating space 212 and the inner surface of the guide hole 213. [

Generally, when the pile is subjected to a vertical load to the lower portion, the wing portion 221 of the expander 22 receives an upward reaction force. In this case, when the mouth piece 2 is made of concrete, the wing portion 221 is subjected to an upward load, and is subjected to friction or impact with the lower portion of the wing portion receiving space 212, There is a possibility that breakage may occur in the heat exchanger 212.

Also, since the magnifying lens 2 advances the diameter at the same time as it rotates, the expanding body 22 receives a reaction force in the lateral direction. At this time, the wing portion 221 is rotated in a plane, and the pressing portion 222 may be damaged or broken by the friction or impact with the guide hole 213.

Therefore, the upper surface of the wing portion accommodating space 212 and the inner surface of the guide hole 213 can be reinforced with a steel plate to prevent the damage of the magnetooptical main body 21.

13, the reinforcing plate 24 may be composed of a lower plate 241, a side plate 242, and a blade storage space protecting plate 243.

Further, the reinforcing plate 24 may also serve as a formwork when manufacturing the sharpener 2.

In this case, as shown in FIG. 14, a mold or a filler 25 for forming a wing storage space 212 is attached to the lower portion of the reinforcing plate 24 to pour the concrete.

The form or filler 25 may be formed in the same ring shape as the outer circumferential surface of the reinforcing plate 24.

When the mold is used, the ring is divided and assembled for demolding, and the releasing agent is applied to the surface. When it is used as the filler (25) such as styrofoam, the styrofoam can be removed after hardening the concrete without splitting.

As shown in FIG. 12, a slime inflow port 26 having a sharp bottom can be detachably coupled to the bottom of the peristalsular main body 21 by the pressure of the pressure body 3.

The slime inflow port 26 prevents the lower slime from flowing into the dispenser 2 at the initial stage of pressurization of the presser 3.

Immediately after the pressing body 3 is moved downward and the expanding body 22 is extended, the pressing body 3 closes the pressing body receiving space 211 inside the quadrangular pyramid body 21, (2).

When the pressurizing body 3 further moves downward and the slime inflow end stopping portion 26 is disengaged from the mouthpiece body 21, the pressurized fluid is discharged to the space between the lower end portion of the mouthpiece body 21 and the slime inflow end stopping portion 26 It is possible to smoothly work hammer bit by helping to discharge cutting slime.

The slime inlet zone 26 is tag-weldable or engageable with the edge plate 27 at the bottom of the pile.

FIG. 15A is a perspective view of the self-diameter pile according to the present invention in which adjacent expanders are overlapped with each other, and FIG. 15B is a perspective view of the self-diameter pile of the present invention formed on the surface corresponding to the guide projection and the guide groove.

15 (a), the widened portion 22 of the widening body 22 is overlapped with the wing portion 221 of the adjacent widening body 22 in a state of being housed in the wing-portion accommodating space 212, .

In this case, a continuous pile-forming portion can be formed on the ground when the expander 22 is expanded.

15 (b), guide grooves or guide protrusions 225 are formed on the upper surface or lower surface of the extension body 22, and guide protrusions or guide grooves (not shown) are formed on the corresponding surfaces of the guide holes 213 216 may be formed so as to guide the extending direction of the expander 22.

FIG. 16 is a perspective view of the self-diameter pile of the present invention provided with the earthed area.

As shown in FIG. 16, the pile main body 1 may further include a paired atrium 12 protruding outward from the pile main body 1 at one side of the pile main body 1.

If the outer diameter of the pore diameter 2 is large, the diameter of the pore hole is inevitably increased to a large extent. In this case, the gap between the pore diameter and the pore hole becomes large at the upper portion of the pile, and eccentricity may occur in the pile.

Therefore, it is preferable to prevent the eccentricity of the pile by connecting the earthed pillar region 12 to the upper side of the pile main body 1 so as to have a size similar to the outer diameter of the pore mouth 2.

A predetermined space for injecting the grout material must be secured between the earthed zone 12 and the perforation hole.

The earthed ribs 12 may be made of concrete, steel, elastic rings or the like. 16 (a) is a plan view of the pile main body 1 in a state in which the edge plate of the pile main body 1 is extended to form a steel pillar atrium 12, FIG. 16 (b) 16 (c) shows a case where the eccentric region 12 of the elastic C-shaped ring such as rubber is fitted in the upper part of the pile body 1, FIG.

Figure 17 is a perspective view of the self-diameter pile of the present invention having a mesh member.

The piercing mouth 2 may be formed of a higher strength concrete than the pile body 1.

For example, the pile main body 1 uses high strength concrete of a general PHC file, and the piercing mouth 2 is not damaged by the impact of the expander 22 when the ground is cut. Therefore, ultra high strength concrete can be used.

In this case, the quadrangular prism (2) also serves to reinforce the tip end of the pile.

As shown in FIG. 17, a mesh member 28 may be provided between the pile body 1 and the piercing mouth 2.

It is also possible to place the pile main body (1) and the piercing hole (2) first by curing, then piling the remaining pile, but this takes a long time to produce.

Therefore, it is preferable to pile the pile body 1 and the piercing mouth 2 at the same time. The mesh member 28 serves as a separator for the concrete portions of the pile body 1 and the piercing mouth 2 during the manufacturing process, And the joining force of the joining portion is increased later to contribute to the integration.

For example, the pile main body 1 and the piercing hole 2 can be integrally formed by filling the concrete in the lower part of the circular mold and centrifugally molding the mold by rotating the mold. In the region of the piercing hole 2, The pile body 1 and the piercing mouth 2 can be manufactured by filling and rotating the high strength concrete.

Of course, in the case of PHC files, centrifugal molding is carried out after the tension of the steel wire.

18 is a cross-sectional perspective view of the self-diameter pile of the present invention equipped with a detachable locking part.

As shown in FIG. 18, a detachable latching portion 218 can be formed on the top of the mouthpiece 2 to engage with ground rotating equipment. Accordingly, the rotating mouthpiece 2 can be rotated by attaching the rotary device to the detachable locking portion 218 and transmitting the rotational force.

After completion of formation of the pile enlarged portion by rotation of the pore hole 2, the residual slime and foreign matter in the pore hole are prevented from flowing into the pile main body 1, To the ground.

FIG. 19 is a view showing a stepwise process of the manufacturing method of the self-diameter pile according to the present invention in the case of pre-drilling.

19 (b), a mold F for manufacturing the pile body 1 is installed on the upper part of the mouth opening 2 as shown in Fig. 19 (a) do. At this time, the quadrangular prism (2) acts as a lower mold of the pile main body (1).

The steel wire ST can be installed beforehand in the bore hole 2 before the mold F is installed and after the steel wire ST is tensed after the form F is installed as shown in Fig. The pile can be completed by casting the concrete in the form (F) by centrifugal molding and curing and then demolding the form (F) as in d).

Since the diameter of the mouthpiece 2 is smaller than that of the pile body 1, it is possible to maximize the production efficiency since the mouthpiece 2 can be mass-produced from the outside when the mouthpiece 2 is manufactured first.

20 and 21 are cross-sectional perspective views of the self-diameter pile of the present invention with a coupling part.

In the case where the piercing body 2 and the pile body 1 are manufactured separately, in order to join the pile body 1 to the upper part of the piercing mouth 2, the pile body 1 may be welded or adhesively joined, can do.

FIG. 20 is a perspective view showing a state in which the upper steel plate fixed to the upper surface of the hollow shaft 2 is used as the engaging portion 4 and the tip of the steel pipe pile is engaged with the engaging portion 4, in the case where the pile body 1 is a steel pipe pile. Welded.

FIG. 21 is a perspective view of a PHC pile according to another embodiment of the present invention. In the PHC pile, a bolt is coupled to a steel plate coupled to the bottom of the PHC pile, And a bolt is fastened in a pipe filled with an adhesive agent to join the pile body 1 and the screw hole 2 with each other.

22 is a view showing the self-diameter pile of the present invention having a support groove.

22 (a) and 22 (b), a support groove 219 may be formed along the circumference on the outer peripheral surface of the wing portion accommodating space 212 of the center body 21.

As a result, after the self-diameter pile is inserted into the perforation hole 6, the joint filler can be sufficiently filled and filled between the perforation hole 2 and the perforation hole 6, Even if the enlarged portion can not be formed, it is possible to prevent the material of the bottom surface of the pile enlargement portion from being caught by the support groove 219 and rising to the upper portion of the perforation hole 6. [

At this time, the fixation liquid 5 is filled in the support groove 219 to prevent the fixing liquid 5 from rising and prevent the lower material of the ground of the pile enlargement part from rising.

The self-diameter pile of the present invention may be formed of a pile body 1 or a cast-in-place pile.

In the case where the pile body 1 is a foundation pile, a method of constructing the self-piercing pile of the present invention comprises: (a) forming a perforation hole in the ground; (b) And the self-diameter pile is inserted into the perforation hole formed in the ground. At this time, the perforation hole can be formed by various methods such as boring or striking.

Thereafter, (c) a cone-shaped pressing body 3 or a fluid pressure body 3 is inserted into the pressing body accommodating space 211 to rotate the pressing body 222, thereby pressing the end of the pressing body 222, 22 extend out of the piercing main body 21 while cutting the surrounding ground under the pierced hole.

At this time, the drill hole 2 may be rotated by the rotation of the pile body 1, or it may be possible to rotate only the drill hole 2 separately from the pile body 1.

After expansion (2), the pressurization body (3) is recovered and the filler is filled in the empty space in the pile to complete the construction.

In the method of constructing the self-diameter pile of the present invention, (a) a perforation hole is formed in the ground, (b) the perforation hole 2 is formed in the perforation hole formed in the perforated hole ground, The process of inserting and inserting it should be performed.

(C) By pressing the end portion of the pressing portion 222 by inserting the cone-shaped pressing body 3 or the fluid pressure body 3 having a conical tip into the pressing body accommodating space 211 while rotating the discoidal mouth 2 So that the expander 22 expands outside the piercing main body 21 while cutting the surrounding ground below the piercing hole.

Finally, (d) Concrete poured into the upper part of the piercing hole (2) to complete the casting piles. It is also possible to install reinforcing materials such as reinforcing net and FRP before pouring concrete.

In this case, the pile may be directly inserted into the ground without previously forming the perforation hole in the ground. In this case, (a) a type of self-diameter pile having the pore hole 2 coupled to the bottom surface of the pile body 1, (3) or a fluid pressure element (3) having a conical tip end is inserted into the pressurizing-body accommodating space (211) while rotating the magnifying orifice (b) So that the expanding body 22 expands outside the scooping main body 21 while cutting the ground.

23 is a cross-sectional view showing an embodiment of the present invention for rotating the mouthpiece.

When the pile body 1 is inserted directly into the ground and it is difficult to rotate the pile body 1 due to the friction between the pile body 1 and the ground, only the pore mouth 2 can be rotated.

23, the roughing steel plate 13 at the lower end of the pile main body 1 is caught in the wing portion receiving space 213 of the piercing main body 21 so that the piercing mouth 2 is pushed into the pile main body 1 And the engaging jaw P formed on the jaw mouth main body 21 is coupled to the rotary jaw 7 above the jaw mouth 2 so that the jaws 2 can be rotated by driving the rotary jaws 7, .

The rotary tool 7 may be a rotary motor, a rotary rod, or the like.

1: pile body 11: hollow
12: Atbam District 13: Mogwari plate
2: Zoom lens 21: Zoom lens body
211: pressure body storage space 212: wing storage space
213: Guide ball 214: Fluid pressure supply passage
215: stopper 216: guide groove
217: Automatic supply line 218:
219: Support groove 22: Extension body
221: wing portion 222: pressing portion
223: latching groove 224: fitting groove portion
225: guide projection 23:
231: fitting projection 24: reinforcing plate
241: Lower plate 242: Side plate
243: Wing compartment storage space protecting plate 25: Filler
26: Slime inflow zone 27: Magical plate
28: mesh member 29: lower member
291: Buoyancy prevention ball 3: Pressure body
31: Foreman 32: Entry and exit ball
33: Horizontal auxiliary pressing body 331, 332:
34: vertical auxiliary pressing body 341:
35: through hole 36:
4: Coupling part 5: Fixing solution
6: perforation hole 7: revolving hole
F: mold G: fluid passage
ST: Steel wire T: Cutting tip
P:

Claims (18)

A piercing main body 1 installed in the ground, a piercing mouthpiece 2 coupled to a lower portion of the pile main body 1 and rotated while being expanded in diameter, and a pushing body 3 for expanding the diameter of the piercing mouthpiece 2 Lt; RTI ID = 0.0 > pile < / RTI >
The pressurized object accommodating space 211 and the wing portion accommodating space 212 are formed on the side surface along the outer circumferential surface of the pressurizing object accommodating space 211, (21) having a cylindrical shape and having a plurality of guide holes (213) formed therein so as to communicate with the guide holes (212); And an arc-shaped wing portion 221 that is received in the wing portion accommodating space 212 and has a cutting tip T coupled to the outer side thereof. The guide wing 213 protrudes from the rear end of the wing portion 221, An expanding body 22 formed of a pressing portion 222 inserted into the pressing portion 222; Respectively,
The pressing body 3 presses the end portion of the pressing portion 222 in the direction of the guide hole 213 in the pressing body accommodating space 211 so that the expanding body 22 slides radially outwardly of the distal end main body 21 (2) is enlarged due to the rotation of the shaft (2).
The method of claim 1,
An end portion of the wing portion 221 of the extension body 22 is located in the pressing body receiving space 211. The pressing body 3 has a conical bottom end,
The upper end of the pressing body accommodating space 211 is opened to move the pressing body 3 downward through the opened space of the pressing body accommodating space 211 so that the extension body 22 And the expanding body (22) is slidingly moved outward by pressing the end of the pressing portion (222).
3. The method of claim 2,
A plurality of horizontal auxiliary pressing bodies 33 are provided on the side surface of the pressing body 3 for slidingly protruding from the pressing body 3 to further push and push the end of the pressing portion 222 of the extending body 22 A self-diameter pile.
The method of claim 1,
The pressurizing body 3 is a fluid and a fluid pressure supply passage 214 is formed in an upper portion of the pressurizing body accommodating space 211 of the quadrangular prism body 21 so as to communicate with the pressurizing body accommodating space 211, The fluid is supplied to the pressurizing body accommodating space 211 through the supply passage 214 and the end of the pressurizing portion 222 of the expanding body 22 is pressed by the fluid pressure so that the expanding body 22 is slid to the outside A self-piercing peg featuring that.
5. The method of claim 4,
Wherein at least one of a side surface of the wing portion (221) and a side surface of the guide hole (213) has a fluid movement path (G) through which the fluid is discharged to the outside.
5. The method of claim 4,
The upper surface of the extension body 22 is formed with an engagement groove 223 having a predetermined length along the extending direction of the extension body 22 and is inserted into the engagement groove 223 at the upper portion of the blade accommodation space 212. And a stopper (215) protruding to limit an extension length of the wing portion (221) is protruded.
The method of claim 1,
When the expander 22 is protruded to the outside from the upper or lower part between the wings 221 of the adjacent extensions 22, the wings 221 move outwardly as the wings 221 move, 221), and a secondary expansion member (23) for closing the space between the inner and outer diameters.
The method according to claim 2 or 4,
Characterized in that the pile body (1) is a concrete pile having a hollow (11) formed therein in the vertical direction, and the pore hole (2) is integrally formed at the lower end of the pile body (1) with concrete.
9. The method of claim 8,
Characterized in that the quadrangular prism (2) has a larger outer diameter than the pile body (1).
In the eighth,
And a reinforcing plate (24) is coupled to an upper surface of the wing portion accommodating space (212) and an inner surface of the guide hole (213).
9. The method of claim 8,
Characterized in that a slime inflow zone (26) with a sharp bottom is detachably coupled to the lower part of the main body (21) by the pressure of the pressure body (3).
The method of claim 9,
Wherein the pile body (1) is further provided at one side thereof with an atrial inferior region (12) protruding outside the pile body (1).
9. The method of claim 8,
Characterized in that the quadrangular prism (2) is formed of a higher strength concrete than the pile body (1).
The method of claim 13,
Characterized in that a mesh member (28) is provided between the pile body (1) and the punch body (2).
The method of claim 9,
Wherein a support groove (219) is formed along the circumference of the outer peripheral surface of the wing portion receiving space (212) of the quadrangular pyramid body (21).
A method of constructing a self-diameter pile according to claim 1,
(a) forming a perforation hole in the ground;
(b) inserting a self-piercing pile into which the piercing hole (2) is coupled at the bottom of the pile body (1) into the piercing hole; And
(c) While pressing the end of the pressing portion 222 by inserting the pressing body 3 into the pressurizing body accommodating space 211 while rotating the centering rod, the expanding body 22 cuts the ground, Expanding to outside; Wherein the pile is constructed of a self-piercing pile.
A method of constructing a self-diameter pile according to claim 1,
(a) forming a perforation hole in the ground;
(b) inserting the mouthpiece 2 into the lower part of the perforation hole;
(c) While pressing the end of the pressing portion 222 by inserting the pressing body 3 into the pressing body receiving space 211 while rotating the centering mouth 2, the expanding body 22 cuts the ground, (21); And
(d) forming concrete pouring holes by pouring concrete into the upper part of the pouring hole; Wherein the pile is constructed of a self-piercing pile.
A method of constructing a self-diameter pile according to claim 1,
(a) inserting a self-piercing pile, which is coupled to the bottom of the pile main body 1, with the piercing mouth 2 into the ground by type, press-fitting or rotation-penetration;
(b) While pressing the end of the pressing portion 222 by inserting the pressing body 3 into the pressing body accommodating space 211 while rotating the centering rod, the expanding body 22 cuts the ground, Expanding to outside; Wherein the pile is constructed of a self-piercing pile.

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